• 专利附录
  • 专利说明
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  • 类似技术
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    • 专利摘要:
    The present invention discloses a skin analyzer (1) having an LED light panel (11) and at least one first polarizer (12). The skin analyzer may provide various types of detection light, namely white light or UV light. By using white light for skin analysis, a pre-image of the examined skin site can be obtained. By analyzing the before image of the examined skin site, the skin condition of the examined skin site, e.g. the pore size or the depth of patches on the skin. By using UV light for skin analysis, it can be determined whether metal residues or acne are present on the skin surface of the examined skin area. By means of the skin analysis device according to the invention, various information about the skin condition can be obtained in order to facilitate subsequent skin consultation.
    公开号:CH713653B1
    申请号:CH01547/17
    申请日:2017-12-15
    公开日:2019-05-15
    发明作者:Tseng Chin-Ming;Su Tai-Wei
    申请人:Li Tek Tech Co Ltd;
    IPC主号:
    专利说明:

    description
    Field of the Invention The present invention relates to a skin analyzer, and more particularly, to a skin analyzer capable of detecting the condition of the skin and the fat and moisture content of a subject's skin.
    Background Art A certain rate of growth is still observed for the medical-cosmetic beauty market and especially for its partial area dealing with the condition of facial skin, although the economy is generally in a downturn. This shows that it is in the nature of man to place much value on a beautiful appearance. The research and development that deals with equipment for medical beauty treatments, thus currently has a great development potential.
    In skin analysis devices currently available, the resulting skin reflection image is poorly resolved and can only provide the examined person or device operator with information on a single parameter of the skin condition, such as skin condition. pore size, skin roughness or skin moisture content. Therefore, to obtain information on various parameters indicative of the condition of the skin, it is necessary to use several different analyzers, making it difficult to provide appropriate advice in the beauty industry.
    OBJECT OF THE INVENTION In view of the above-mentioned problem, a skin analyzer is to be provided in which the resulting reflection image of the skin has a higher resolution, thereby meeting the requirement of the users, at the same time information on a variety of different skin conditions of an examined Person characterizing parameters, such as skin roughness, skin softness, or metal content at the skin surface, thereby minimizing the problems an operator encounters using conventional skin analyzers and increasing the efficiency of corresponding beauty counseling.
    Technical Solution To solve the above-mentioned problem, the present invention provides a novel skin analyzer in which one or more polarizers are provided at at least one suitable position to thereby obtain a higher resolution for the measured skin reflection image, and thus further analysis index relating to the skin condition of an examined person can be determined in order to obtain information on various parameters characterizing the skin condition of the examined person, such as eg Spots, wrinkle depth and pore size.
    According to the present invention, a skin analyzer is further provided, wherein LED lamps that emit UV light are provided in the skin analyzer, whereby the skin analyzer according to the invention can perform a measurement to determine whether on the skin surface cosmetic metal residues are located. Furthermore, it can be determined whether at this time on the skin of the person examined other events, such as an increase of bacteria or cornification are observed.
    The present invention also provides a skin analyzer in which a fat-moisture-detecting means is provided whereby a skin moisture content and a skin fat content of an examined person are determined by the frequency of a fat and moisture analysis on the skin of the person being examined can be further assessed on the basis of the skin moisture content and the skin fat content, how soft the skin of the examined person is.
    Thus, according to the present invention, the present invention provides, first, a skin analyzer, the skin analyzer comprising as components an LED light panel, a first polarizer, a lens module, a main circuit board, a bottom cover, and a top cover. On the LED light panel, a plurality of LED lamps which emit white light and a plurality of LED lamps which emit UV light are arranged to provide the detection light required for the use of the skin analyzer. The first polarizer is disposed on the LED light panel, the first polarizer serving to filter the light reflected from a face of an examined person when the detection light is projected thereon to thereby obtain a polarized light signal. The lens module has a terminal connected to a terminal of the LED light panel, the lens module configured to receive the polarized light signal and then transmit an electrical signal generated therefrom to the main circuit board. The main circuit board has a terminal connected to a terminal of the lens module, wherein a light control switch, a recording control switch, a power switch, a wireless transmission module, and a signal processing module are disposed on the main circuit board, the main circuit board receiving the electrical signal from the lens module thereafter Processes signal to a pre-image of the skin of the person examined and further transmits to the wireless transmission module, wherein the wireless transmission module, the forward image of the skin of the person being examined to a receiving device on. By the light control switch, it is possible for the operator to switch between the LED lamps that emit white light and the LED lamps that emit UV light, depending on the purpose, to provide the detection light. The recording control switch is for recording control of the lens module, so that the operator can receive a pre-image of the skin of the examined person by a recording. Further, a loading plate is provided, wherein a terminal of the loading plate is connected to the other terminal of the main circuit board, wherein the loading plate is used to perform charging operations. Furthermore, a lithium battery is disposed on the main circuit board and serves to provide the power required for the use of the skin analyzer. The lower cover has a receiving space accommodating the LED light panel, the lens module, the main circuit board, the charging plate, and the lithium battery. The top cover is connected to the bottom cover, further comprising a trim ring and a plurality of buttons on the top cover, the buttons being connected to the light control switch, the recording control switch, and the power switch so that the operator selects the desired detection light through the buttons Start the lens module and operate the lens module to record the pre-image of the skin of the person examined and the operator is supported when starting the skin analyzer. In addition, an LED lamp cover may be provided with the LED lamp cover disposed at the front ends of the upper cover and the lower cover to facilitate connecting the upper cover to the lower cover.
    The skin analyzer according to the present invention may further comprise a fat and moisture detecting portion, wherein a terminal is provided on the fat and moisture detecting portion, which is connected to the LED lamp cover, wherein the fat and moisture Detecting portion comprises a grease moisture sensing probe, a front cover, a front cover trim ring and a dust cover, the grease moisture sensing probe being connected to the front cover trim ring through the front cover, the dust protection cap being disposed on the front cover; Moisture detection probe is configured to perform a frequency-based fat and moisture analysis on the skin of the person being examined, after which the frequency obtained in the fat and moisture analysis of the examined person's skin is sent to the receiving device.
    The skin analyzer may further include an end cover portion, wherein the end cover portion is disposed at the rear ends of the top cover and the bottom cover, wherein the end cover portion comprises a Endabkleidungszierring, an end cover and a sealing ring for the end cover, wherein the sealing ring for the end cover is disposed on the end cover, wherein one end of the end cover is connected to the Endabdeckungszierring, wherein the Endabdeckungsabschnitt serves to stabilize the skin analyzer in use.
    Since the dermal analyzer has a plurality of LED lamps which emit white light and a plurality of LED lamps which emit UV light, the pre-images of the skin of an examined person relating to the condition of the skin can be obtained by means of the skin analyzer, if When using the skin analyzer, the operator selects white light as the detection light. If UV light is selected as the detection light, it can be detected by means of the skin analyzer whether the skin of the examined person has abnormalities at this time, e.g. Metal residues on the skin, clogged pores or cornification. Further, the dermal analyzer may include a fat and moisture detection section for performing a fat and moisture analysis on the subject's skin to obtain a frequency, further comprising a wireless transmission module in the dermal analyzer, through which the obtained Before the image of the skin and the frequency obtained from the fat and moisture analysis of the skin of the examined person can be sent to a receiving device, the receiving device is equipped with an application software (Apps) through which the obtained before-image of the skin and the The frequency obtained from the fat and moisture analysis of the skin of the person being examined can be separately analyzed and compared, finally indicating an index of analysis characterizing the skin condition of the person being examined and the fat and moisture content of the examined person's skin and the operator, viz By means of information on a multiplicity of different parameters regarding the skin condition of a person being examined, it is possible to obtain subsequent beauty advice.
    The skin analyzer according to the present invention may be used for an analysis method for obtaining information on the skin condition of an examined person, this analysis method comprising the steps of: starting the skin analyzer and starting the LED bulbs emitting white light; by the operator, - Performing a connection test between the dermal analyzer and a receiver by the operator, - Aligning the opening of the dermal analyzer on the person's skin to be examined by the operator to perform a skin analysis, and - Decision by the operator, as appropriate An analysis of the skin condition of the person should be carried out.
    In this way, with the aid of the abovementioned analysis method, the operator can obtain an accurate picture of the condition of the skin of an examined person and obtains information on various parameters, such as e.g. the pore size, the depth of spots or the depth of wrinkles, which facilitates subsequent consultation.
    In order to ensure that the analysis index indicative of the skin condition of the person being examined can be displayed by means of the skin analyzer according to the invention of an examined person and / or an operator, so that the examined person and / or the operator obtain an accurate picture of the skin condition of the examined person Furthermore, in the analysis method for analyzing the skin condition of an examined person by means of the skin analyzer according to the invention, after the pre-image of the skin of the person being examined has been sent to the receiving device, application software (app) of the receiving device for carrying out an analysis method can be started. which comprises the steps of: pre-processing the skin image by the skin pre-image of the skin by the app to obtain an image of the skin of the person being examined, wherein the pre-image of the skin of the person examined in advance by performing the Kam performed by the lens module of the skin analyzer and processed by the signal processing module, - performing an improvement of the color contrast of the image of the skin of the person being examined by the app to obtain an image of the skin of the examined person with a higher contrast, - performing a classification the higher-contrast image of the examined person's skin corresponding to an analysis target by the app, whereby a classification of skin defects and the skin texture can be carried out by the image-processing app of a mobile device on the basis of the higher-contrast image of the skin of the examined person, and Image of the skin of the person being examined by the app to obtain the analysis results, wherein the analysis results of the person examined are displayed in the form of an analysis index, wherein the post-processing an image edge detection and the analysis of Bildfa includes rbschichten.
    By the analysis method, the receiving means for the person being examined and the operator can provide an analysis index indicative of the skin condition of the person being examined, by which simultaneously information on a variety of different parameters related to the skin condition of the person being examined, such as the depth of the spots Pore size or the depth of fold can be obtained.
    In order to ensure that the fat and moisture content of the skin can be displayed by means of the skin analyzer according to the invention of an examined person and / or the operator, the skin analysis device according to the invention can also be used for an analysis method for analyzing the fat and moisture content of the skin , By the fat-moisture detection probe, a fat and moisture impedance signal of the skin of the examined person is detected, wherein the impedance signal of the person's skin is processed by means of the main circuit board and converted into a frequency characterizing the fat and moisture analysis of the examined person's skin which is sent to the receiving device. Subsequently, the following analysis method is carried out, the analysis method comprising the following steps: evaluating the frequency from the fat and moisture analysis by the app provided in the receiving device in order to determine the skin moisture content, the skin fat content and the skin softness of the examined person, and Providing the results of the evaluation to the examined person and / or the operator by means of the receiving device.
    By this analysis method, the person under investigation and / or the operator can simultaneously obtain a variety of different skin-identifying analysis results, such as the skin moisture content, the skin fat content and the skin softness.
    Since the skin analyzer according to the invention is equipped both with LED lamps which emit white light and with a fat-moisture detection probe, with the same device various information, such as e.g. Before-pictures of the skin and a frequency from a fat and moisture analysis of the skin of the examined person, are obtained. By an appropriate analysis method, the information obtained (e.g., the aforementioned pre-images of the skin and frequency from a fat and moisture analysis) can be analyzed. Thus, a variety of different parameters may provide information on the skin condition of a subject being examined, such as a patient's condition. the pore size, stain depth, texture depth, skin roughness, wrinkle depth, skin moisture content, skin fat content, and skin softness are maintained at the same time. Moreover, since the skin analyzer according to the invention is likewise equipped with LED lamps which emit UV light, it can also be detected and immediately recognized whether abnormalities exist on the examined person's skin, such as, for example, metal residues, clogged pores or keratinization. Furthermore, those skilled in the art, e.g. Beauticians provide investigators with more targeted, user-specific beauty recommendations based on the information they receive, thereby improving the efficiency of skin consultation.
    Brief Description of the Drawings In the following, the invention will be described in greater detail with reference to the accompanying drawings, which illustrate the invention in a schematic manner. Showing:
    1A is an exploded view of the entire structure of the inventive skin analysis device,
    1B is a partially enlarged exploded view of the inventive skin analysis device,
    1C is an enlarged exploded view of a fat and Feuchtigkeits-Erfassungsab section of the skin analyzer according to the invention,
    2A is a schematic representation of the structure of the skin analysis device according to the invention,
    2B shows a schematic representation of the structure of the fat and moisture detection section of the skin analysis device according to the invention,
    3A to 3E representations of the achieved by arranging the polarizers imaging effect,
    4A is a circuit diagram of the charge and discharge circuit for the fat and moisture detection of the skin of the examined person,
    4B is a schematic representation of the charging and discharging cycles of the capacitors,
    5A shows a flow chart of the operation of the skin analysis device according to the invention,
    FIG. 5B is a flowchart of the skin pre-image analysis method of the examined one. FIG
    Person,
    5C is a flowchart of the analysis method for the fat and moisture content of the skin,
    Fig. 6A is a schematic representation of the pore contrast of the image of the skin of the examined
    Person,
    Fig. 6B is a schematic representation of the texture contrast of the image of the skin of the examined
    Person,
    Fig. 6C is a schematic representation of the contrast of the image of the skin of the examined
    Person,
    Fig. 6D is a schematic representation of the wrinkle contrast of the image of the skin of the examined
    Person,
    Fig. 6E is a schematic representation of the fluorescence response of a metal on the skin in UV detection, and
    Fig. 6F is a schematic representation of the obtained by means of UV light detection of Porenver blockages and cornifications.
    DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In order to provide a thorough understanding of the technical content of the present invention, the preferred embodiments are described below, so that the present invention as described by one skilled in the art can be readily implemented. However, the well-known basic principles of optical and electrical communication and image processing used in the present invention will not be described in the following embodiments. However, it should be clarified herein in advance that in the described features and in the described embodiments of the inventive skin analysis device, the connections between the components are each realized by metal wires. Furthermore, the embodiments will be described in detail with reference to the accompanying drawings, in which the shapes and relative sizes of the components in the drawings are given by way of illustration and a better understanding of the contents of the embodiments, but the shapes and relative sizes of the components are not should be limited to it.
    Reference is made to FIGS. 1A, 1B and 2A. 1A shows an exploded view of the overall structure of the skin analysis device according to the invention. 1B shows a partially enlarged exploded view of the skin analysis device according to the invention, and FIG. 2A shows a schematic representation of the structure of the skin analysis device according to the invention. First, reference is made to FIG. 1A. The skin analyzer 1 comprises an LED light panel 11, at least a first polarizer 12, a lens module 14, a main circuit board 15, a lower cover 18, and an upper cover 19 as components. The LED light panel 11 includes a plurality of LED lamps 111 that emit white light, and a plurality of LED lamps 112 that emit UV light that are respectively disposed on the LED light panel 11, wherein in the center of the LED light panel 11 a hole portion 113 is provided, and the LED lamps 111 which emit white light and the LED lamps 112 which emit UV light serve to provide the detection light required for the use of the skin analyzer 1. In one embodiment, the number of LED lamps 111 that emit white light and the number of LED lamps 112 that emit UV light are eight each. Further, the arrangement of the LED lamps 111 which emit white light and the LED lamps 112 which emit UV light are realized to be arranged around the hole portion 113, thereby defining a concentric circle. Incidentally, the LED bulbs 111 emitting white light are outside the concentric circle, and the LED bulbs 112 emitting UV light are near the central portion of the concentric circle. The purpose of arranging the LED lamps 111 which emit white light outside the concentric circle is to thereby record a pre-image of the skin of an examined person. The purpose of arranging the LED lamps 112 which emit UV light in the vicinity of the central region of the concentric circle is to thereby make it possible to detect whether abnormalities on the skin of the person being examined, e.g. Metal residues, clogged pores or keratinization, present. For example, if there are metal residues, a fluorescent phenomenon can be observed on the skin of the person being examined, and the person being examined is accordingly informed that the cosmetic used by him is likely to contain a metal component. For example, if red patches are observed on the skin, it means that bacterial proliferation causes pore clogging. If, for example, white patches are observed on the skin, this means that the pores of the skin become blocked by keratinization. Further, referring to Fig. 1A, the first polarizer 12 according to the present invention is a flat plate, wherein a plurality of through holes 121 are provided at the periphery of the first polarizer 12, the number of which corresponds to the number of LED lamps 111 emitting white light. wherein the number of the plurality of through holes 121 of the first polarizer 12 may be selected according to the number of the existing LED lamps 111 emitting white light, but is not limited thereto. It is apparent that the plurality of through holes 121 of the first polarizer 12 serve to pass the detection light, which is generated by the LED bulbs 111 that emit white light, through the plurality of through holes 121 of the first polarizer 12 and onto the skin projected person can be projected. When the detection light generated by the LED lamps 111 emitting white light impinges on the subject's face, the light is scattered therefrom because the examined person's facial skin is not a smooth surface and / or the skin surface has some fat and / or has moisture content. This stray light reflected back from the skin may then pass through the first polarizer 12, whereby the scattered light reflected back from the skin is thus filtered by the first polarizer 12, producing a polarized light signal to increase the resolution of the image of the skin. It is obvious that in the skin analyzer of the present invention, the first polarizer 12 may be constructed of a directional material such as polyvinyl alcohol, but the invention is not limited thereto in the present embodiment.
    In order to allow an even better resolution of the recording of the examined skin site, the number of polarizers can be further changed in the skin analyzer of the present invention further. In order to control or adjust the brightness of the detection light generated by the LED lamps 111 emitting white light, in a preferred embodiment of the invention, another polarizer, namely, a second polarizer 13, may be located near the skin Side of the first polarizer 12, as shown in Fig. 1B. In the center of the second polarizer 13, a through hole 131 is formed, which corresponds to the hole portion 113 of the LED light panel 11, wherein a plurality of through holes 132 between the edge and the passage hole 131 of the second polarizer 13 are provided, the number of these through holes 132nd is tuned to the number of LED lamps 111 that emit white light, wherein the number of the through holes 132 is varied so that the detection light generated by the LED lamps 111 that emit white light can be shielded to thereby prevent the Adjust the brightness of the image of the skin and thus increase the resolution. In a preferred embodiment, the number of through holes 132 is four, and an embodiment with this number means that the brightness of the entire detection light is reduced, and as shown, when eight LED lamps 111 emitting white light generate the detection light That is, only four of the LED bulbs 111 that emit white light can pass through the generated light as the detection light through the through-holes 132 and be irradiated on the skin, generated by the other four LED bulbs 111 that emit white light Light can be radiated only after passing the second polarizer 13 to the skin. Then, when the light generated by the LED bulbs 111 emitting white light passes through the second polarizer 13 and is irradiated to the skin and reflected there, the back-reflected light passes through the through hole 131 of the second polarizer 13. Subsequently, the scattered light is filtered out by means of the first polarizer 12, and finally imaging processing is carried out by the objective module 14. It is obvious that the brightness of the detection light generated by the LED lamps 111 emitting white light can be controlled by the arrangement of the second polarizer 13. The additional second polarizer 13 may be disposed at a side end located near the top cover 19. However, like the first polarizer 12, the second polarizer 13 may be composed of a directional material such as polyvinyl alcohol, but the invention is not limited thereto either.
    Referring to Fig. 1A, one terminal of the lens module 14 is connected to one terminal of the LED light panel 11 to receive the polarized light signal. More specifically, the lens module 14 includes a camera unit 141 and an FPC board 142, the camera unit 141 being inserted into the hole area 113 of the LED light panel 11 so that one terminal of the lens module 14 is connected to one terminal of the LED light panel 11 , Here, the camera unit 141 may be an image sensor (CMOS image sensor) made of a complementary metal oxide semiconductor. Further, the FPC board 142 is connected to a terminal of the camera unit 141 and serves to provide the power required by the camera unit 141 and to process a photoelectric conversion signal. When the camera unit 141 of the lens module 14 receives a polarized light signal, the received polarized light signal can be converted into an electrical signal by means of the complementary metal oxide semiconductor (CMOS) disposed in the camera unit 141. Subsequently, the electrical signal is transmitted to the main circuit board 15 for performing image signal processing.
    Referring further to Figs. 1A and 1B, a connector 151 is disposed at one end of the main circuit board 15, wherein the connector 151 can be connected to another terminal of the FPC plate 142 of the lens module 14, so that the lens module 14 and the Main circuit board 15 are interconnected. Further, a light control switch 152, a recording control switch 153, a power switch 154, a wireless transmission module 155, and a signal processing module 156 are disposed on a first side of the main circuit board 15. It is obvious that the light control switch 152, the recording control switch 153 and the power switch 154 are connected to the circuit on the main circuit board 15, the power switch 154 being connected via the connector 151 to a lithium battery 17 on the other side of the main circuit board 15 the light control switch 152 is connected to the LED lamps 112 that emit UV light, and the recording control switch 153 is connected to the lens module 14. Further, the wireless transmission module 155 and the signal processing module 156 are disposed in the main circuit board 15 and connected to each other.
    Referring still to Figs. 1A and 1B, a terminal of a charging plate 16 is connected to the lithium battery 17, whereby the charging plate 16 can perform charging operations. Through the charging processes, the current required for the use of the skin analyzer 1 can be temporarily stored in the lithium battery 17, the lithium battery 17 being arranged on the main circuit board 15 and providing the power required for the use of the skin analyzer 1 in use.
    Referring still to Figs. 1A and 1B, the lower cover 28 has a receiving space 181 in which the LED light panel 11, the lens module 14, the main circuit board 15, the charging plate 16 and the lithium battery 17 are accommodated. The upper cover 19 is connected to a lower cover 18. Further, a trim ring 191 and a plurality of buttons 192 are formed on the top cover, and the plurality of buttons 192 are respectively connected or at least brought into contact with the light control switch 152, the reception control switch 153, and the power switch 154, whereby the operator inputs the skin analyzer via the buttons 192 1 for performing a skin analysis on a person to be examined, and allows the operator to select the desired detection light according to the various uses when using the skin analyzer 1 and to control the lens module 14 by the acquisition control switch 153 to display the before-image to get the skin of the examined person. The LED lamp cover 20 is disposed at the front ends of the upper cover 19 and the lower cover 18 and serves to strengthen the connection of the upper cover 19 with the lower cover 18. At the same time, the mounted LED lamp cover 20 at its open end a circular Opening 21, wherein the circular opening 21 can be brought into contact with the skin of the person to be examined. In a preferred embodiment, a mounting unit is further disposed on the LED lamp cover 20, whereby the connection of the LED lamp cover 20 with the lower cover 19 and the upper cover 18 is even more stable.
    Reference is again made to FIG. 1A, which shows that an end cover section 120 is also provided on the skin analysis device 1 according to the invention. The end cover portion 120 is disposed at the rear ends of the lower cover 19 and the upper cover 18. The end cover portion 120 includes an end cover trim ring 1201, an end cover 1202, and an end cover sealing ring 1203, wherein the end cover sealing ring 1203 is disposed on the end cap 1202 with one end of the end cap 1202 connected to the end cap trim ring 1201. The end cover portion 120 serves to stabilize the connection state of the upper cover 18 with the lower cover 17 of the skin analyzer 1, so that the skin analyzer 1 is more stable and secure in use.
    According to FIG. 2A, a schematic representation of the structure of the skin analysis device according to the invention is shown. As shown in Fig. 2A, the inventive skin analyzer 1 includes an LED light panel 11, a first polarizer 12, a lens module 14 and a main circuit board 15, wherein at one end of the main circuit board 15, a connector 151 is provided, wherein the connector 151 with a corresponding terminal of the FPC plate 142 of the lens module 14 is connected, whereby the lens module 14 is connected to the main circuit board 15. Further, a light control switch 152, a recording control switch 153, a power switch 154, a wireless transmission module 155, and a signal processing module 156 are disposed on a first side of the main circuit board 15. It is obvious that the light control switch 152, the recording control switch 153 and the power switch 154 are connected to the circuit formed on the main circuit board 15. When the power switch 154 is turned on by the operator, the LED lamps of the LED light panel 11 emitting white light 111 and the lens module 14 are started so that when the operator operates the circular opening 21 of the LED lamp cover 20 of the skin analyzer 1 a skin site of a person to be examined, an image of the skin can be obtained by the lens module 14 by means of the light provided by the LED lamps 111, which emit white light. The light control switch 152 is connected to the LED lamps 112 that emit UV light, and serves to switch from the LED lamps 111 that emit white light to the LED lamps 112 that emit UV light as a detection light source. For example, if the person being examined wishes to know if any cosmetic metal residues have remained on their skin, the light control switch 152 may be actuated. At this time, the circuit is switched to provide the current to which the LED lamps 112 that emit UV light. When the radiation of the ultraviolet light emitting LED lamps 112 hits the skin, it can be determined whether there are abnormalities on the skin of the person being examined, e.g. Metal residues and clogged pores exist. The recording control switch 153 is connected to the lens module 14 and is used to control whether an image of the skin site being viewed by the skin analyzer 1 is to be taken. When the operator wants to take a picture, he presses the recording control switch 153. At this time, an image of the examined skin area is taken with the lens module 14 of the skin analyzer 1. Since the wireless transmission module 155 and the signal processing module 156 of the main circuit board 15 are connected to each other, after pressing the recording control switch 153 and after image acquisition for the subject skin area with the lens module 14, an electrical signal sent from the lens module 14 by means of the signal processing module 156 and received in a pre-image signal of the skin of the person being examined is converted. Thereafter, the pre-image signal of the examined person's skin is transmitted to the wireless transmission module 155. Subsequently, the before-image of the skin of the examined person is further sent to the receiving device 2 and finally the before-image of the skin of the examined person is processed by an application software (app) of the receiving device 2.
    Referring still to Fig. 2A, the receiving device 2 may be a tablet or a smartphone, wherein the above-described image transfer operation may be performed in a wireless communication mode (WLAN or Bluetooth connection). Here, the light control switch 152 allows the operator to switch between the LED bulbs 111 that emit white light and the LED bulbs 112 that emit UV light, so that the operator can select the appropriate detection light source according to the intended use when using the skin analyzer 1 , The power switch 154 is for controlling an on / off state of the skin analyzer 1. The recording control switch 153 serves to control whether to record with the lens module 14 so that the operator can take a picture of the skin of the person being examined to record the before -Picture of the skin of the examined person.
    At this point, the imaging function achieved by the polarizers of the skin analyzer 1 will be described in detail. When the skin analyzer 1 is not equipped with polarizers, the eight LED lamps 111 that emit white light directly illuminate the subject's skin to be examined (such as the subject's face), upon encountering the light of the LED lamps light is reflected on the skin area. If that from the examined skin site, e.g. the subject's face, incoming reflected light is not filtered and goes directly into the lens module 14 for imaging, this results in the background of the pre-image of the examined person's skin being generated by the lens module 14 being too white and poor Image resolution. The results of the imaging are shown in Fig. 3A. The standard deviations of all three primary colors are too small (for example, the standard deviation for "red" is only 2.373, for "green" only 2.776 and for "blue" only 9.168), whereby the distribution of the color and noise ratio of the three primary colors is not uniform , In addition, the gray level value is too high, causing the brightness to be too high, whereby the resolution of the pre-image of the subject's skin is poor. As a result, the actual condition of the skin of the person being examined can not be correctly imaged, which makes the subsequent analysis of the skin condition of the examined person difficult. On the other hand, with the skin analyzer 1 of the present invention shown in the embodiment, the above problem, namely, a too white background of the pre-image of the skin of the examined person having a poor image resolution, can be eliminated.
    In one embodiment of the invention, with which the imaging effect can be shown, a second polarizer 13 is disposed on the located near the skin side of the LED light panel 11. In this case, only the detection light generated by four of the eight LED lamps 111 emitting white light (i.e., only half of the original number) may pass through the through holes 132 for the most part and strike the skin. When the reflected light then passes through the second polarizer 13, most of the light passes through the through hole 131, whereby a portion of the stray light reflected by the skin can be filtered out by the second polarizer 13, thereby attenuating the intensity of the light entering the lens module 14 and thereby a pre-image of the subject's skin can be obtained, whereby a higher resolution can be achieved, the results of the corresponding imaging of Figure 3B being apparent. Although the standard deviations for the three primary colors have improved (for example, the standard deviation for "red" is 4.830, for "green" is only 7.768 and for blue is only 12.018), the distribution of the color and noise ratio is the three primary colors not yet even and the grayscale value is still too high. Accordingly, the brightness is still too high, so that the dissolution of the pre-image of the skin of the person being examined is still poor and the real state of the skin of the person being examined can not be properly represented, which makes the subsequent analysis of the skin condition of the examined person difficult ,
    To solve the problem of poor resolution of the pre-image of the subject's skin (namely the problem of the background of the image being too white), where the image is too bright due to too high a gray scale value, according to the invention, a skin analyzer also becomes 1, in which the first polarizer 12 is disposed at the side of the LED light panel 11 located near the skin site to be examined. The detection light generated by the LED lamps 111 that emit white light may pass through the plurality of through holes 121 located at the periphery of the first polarizer 12, respectively, and be irradiated on the skin. Subsequently, the stray light formed when hitting the skin is filtered out by the first polarizer 12 when the reflected back light passes through the first polarizer 12. Thereafter, an image acquisition is performed by means of the lens module 14. The results of the image acquisition are shown in FIG. 3C. Here, the standard deviations of the three primary colors approach the median (for example, the standard deviation for "red" is 9,019, for green only 11,014 and for blue only 11,208) and the distribution of the color and noise ratio for "green" and "blue »Is more even. However, the distribution of the color and noise ratio for "red" is still not uniform. However, it is obvious that an improvement has been made in the problem of the high grayscale value. Consequently, the skin analysis device 1 according to the invention can be used to obtain a pre-image of the skin corresponding to the actual condition of the skin of the examined person, whereby a subsequent analysis of the skin condition of the examined person can be carried out with this before-image. However, there is still the problem of the white background.
    In order to improve the above-mentioned problem of the white background of the pre-image of the skin of the examined person, according to the invention yet another preferred embodiment is provided. Here, a first polarizer 12 and a second polarizer 13 are simultaneously arranged in the skin analyzer 1. The arrangement positions of the first polarizer 12 and the second polarizer 13 are shown in Fig. 1B. In this case, the second polarizer 13 is disposed on the near the skin or in the vicinity of the LED lamp cover 19 located side of the LED light panel 11, wherein the first polarizer 12 between the second polarizer 13 and the LED light panel 11th is arranged, wherein the first polarizer 12 and the second polarizer 13 overlap each other. When the polarization rotation angle between the first polarizer 12 and the second polarizer is 130 ° or 180 °, i. when the molecular arrangement of the composition of the two polarizers is arranged horizontally, according to the preferred embodiment, most of the light reflected back from the skin passes first through the through hole 131 of the second polarizer 13 and then through the first polarizer 12, the first polarizer 12 can filter out the scattered light reflected back from the skin, whereby the scattered light penetrating into the lens module 14 is filtered out. Subsequently, by means of the lens module 14, the imaging. The results of the imaging are shown in FIG. 3D. The standard deviations of the three primary colors are even closer to the median (for example, the standard deviation for "red" is 11.184, for green only 12.717 and for blue only 12.413), so that the color distribution of the three primary colors is more uniform. It is obvious that the noise of the three primary colors is still too strong, but an improvement has already been made in the problem of the high gray level value. Consequently, the skin analysis device 1 can be used to obtain a pre-image of the skin that corresponds to the actual condition of the skin of the person being examined, and to perform a subsequent analysis of the skin condition of the examined person with this pre-image.
    In a preferred embodiment, as explained in the preceding paragraph, most of the light reflected from the skin passes first through the through hole 131 of the second polarizer 13 and then through the first polarizer 12 when the polarization rotation angle between the first polarizer 12 and the second polarizer 13 is 90 ° (orthogonal), ie when the molecular arrangement of the composition of the two polarizers is vertically aligned. In this case, the first polarizer 12 can filter out the scattered light reflected from the skin, as a result of which the stray light penetrating into the objective module 14 is filtered out (removed). Subsequently, an imaging takes place by means of the objective module 14. The results of the imaging are shown in Fig. 3E. Here, the standard deviations of the three primary colors are very close to the median (for example, the standard deviation is 8.694 for "red", only 9.048 for "green" and only 9.088 for "blue"), whereby the color distribution of blue and the color distribution of green are more uniform, wherein the distribution of the color and noise ratio of red is more uniform than in the illustration in Fig. 3D. It is obvious that an improvement has already been achieved with respect to the problem of the high gray level value. Consequently, the skin analysis device 1 can be used to obtain a pre-image of the skin that corresponds to the actual condition of the skin of the person being examined, and to perform a subsequent analysis of the skin condition of the examined person with this pre-image.
    Based on the imaging effect on a pre-image of the skin of the person being examined, which is obtained by the different arrangements of polarizers in the skin analyzer 1, it can be seen that with regard to the problem of too high a gray scale value already by an arrangement of at least one first polarizer 12 in the skin analyzer 1 an improvement can be achieved. The pre-image of the examined person's skin, which is thus obtained with the skin analysis device 1, is good enough for a subsequent analysis of the skin condition of the examined person. In particular, the pre-images of the examined person's skin obtained by the combination of a first polarizer 12 and a second polarizer 13 in the skin analyzer 1 are well suited for the subsequent analysis of the skin condition of the person being examined, irrespective of whether the angle of rotation between the first polarizer 12 and the second polarizer is 130 ° or 180 ° or 90 ° (orthogonal). The imaging effect for the various arrangements of the polarizers is summarized in Table 1.
    Table 1
    Arrangement of Without Polarisato- Arrangement of an Arrangement of an Arrangement of an Arrangement
    Polarizers ren second polarisa- first polarisa- and a nes first and tors tors 12 second polarisa- a second sector 12, 13, where- polarizer at the rotary 12, 13, where kel between the rotation angle of the first polarisa- between the gate 12 and the first polarizer second polarizer 12 and gate 130 ° or 180 ° the second. Polarizer 13 is 90 °. Although the image is allowed to be contrasted, the contrast in the image allows a little image contrast. The contrast in the image allows the coloring and amplification, but the representation of the representation
    Intoxication is the distribution of actual actual delivery of the actual; Too high of the staining and skin stalls of the skin
    Grayscale noise level of the exam- ines examined the skin and too high helix of the third person and person, however, is investigative (as shown in Fig. Basic colors nor the distribution of the noise of the th person 3A). not even of the color and three primary colors and the color and the gray-to-noise ratio nor is there still noise of the three strong (as shown in Fig. ratio of the three is too high and thus basic colors is shown 3D) , The background color is more uniform, is uniformly white (as in, however, the red is sig (as in Fig.
    Fig. 3B is oversaturated (as shown in Fig. 3E). shown in Fig. 3C).
    Since the skin analyzer 1 according to the present invention can provide two different types of detection light, namely white light and UV light, two different types of information can be obtained with regard to the skin condition of the person being examined. One type of information is based on analyzing a pre-image of the subject's skin to be examined by an associated analysis method, wherein the pre-image of the test subject's skin site is further processed by an app of the receiver 2 based on the original image , whereby various analysis results, which characterize the skin condition of the examined person, can be obtained, which can then be made available to the examined person and the operator, in order to evaluate the skin condition of the examined person.
    In this case, the skin condition may be affected by various features, e.g. Spots that are skin texture, pores, and / or wrinkles. The other type of information that can be obtained according to the invention relates to the detection of metal residues on the skin of the examined person. If metal residues, such as Mercury metal on the skin, after irradiation with UV light, shows a fluorescent reaction on the skin of the examined person, whereby the person examined can be informed whether metal components are contained in the skin care products used by it. In addition, other skin conditions, such as acne and cornification of the skin, can be visualized by exposure to UV light.
    In order to ensure that the skin analysis device 1 according to the invention simultaneously has a function for determining the fat and moisture content of the skin of the examined person, the skin analysis device 1 according to the invention can also be equipped with a fat-moisture detection device 130. With regard to an embodiment of the fat-moisture detection device 130, reference is made to FIGS. 1C and 2B. Fig. 1C is an enlarged exploded view of a fat and moisture detecting portion of the skin analyzer according to the present invention; and Fig. 2B is a schematic diagram showing the structure of the fat and moisture detecting portion of the skin analyzer of the present invention. Reference is first made to Fig. 1C. The grease-moisture detecting device 130 is disposed at a front end of the skin analyzer 1 (namely, at the skin-contacting end on the opposite side of the end cover portion 120) and is connected to the LED lamp cover 19. As shown in FIG. 1C, the grease-moisture detecting device 130 includes a grease-moisture detecting probe 1301, a front cover 1302, a front cover trim ring 1303, and a dust cover 1304. The front cover 1302 is provided with receiving holes 1305. Through the receiving holes 1305, the grease-moisture detecting probe 1301 can be fixed inside the front cover 1302, and can also be connected to the receiving device 1306 of the front cover trim ring 1303. Moreover, a circuit board (not shown) is disposed in the receiver 1306 which is connected to the connector 151 of the main circuit board 15 and serves to allow the grease-moisture detection probe 1301 to be brought into contact with the skin and the grease and moisture content of the examined person's skin is converted into an impedance signal and transmitted to the main circuit board 15. Thereafter, the fat and moisture content indicative skin impedance signal of the person being examined is processed using the signal processing module 156 of the main circuit board 15 to obtain a frequency signal from the fat and moisture analysis of the examined person's skin. Subsequently, the frequency signal from the fat and moisture analysis of the examined person's skin is sent to the receiving device 2 by the wireless transmission module 155 as shown in Fig. 2B. Thereafter, the frequency signal from the fat and moisture analysis of the skin of the person being examined by the app of the receiving device 2 is evaluated to obtain the analysis results. Finally, the analysis results of the examined person and the operator are displayed by means of the receiving device 2, for example on a display of the receiving device 2. The number of the grease-moisture detection probes 1301 may be two. Here, the operating state of the grease-moisture detection probes 1301 can also be controlled via the power switch 154 of the main circuit board 15. In addition, the dust cap 1304 may be optionally disposed on the front cover 1302 to protect the lens module 14 and the grease-moisture detecting device 130 in the skin analyzer 1, and moreover to keep out dust and other foreign matter, so that an impairment caused by dust and other foreign matters of the lens module 14 and the fat-moisture detection device 130 in the skin analyzer 1 can be avoided.
    Referring to the following example, the technical contents are disclosed with which the frequency signal from the fat and moisture analysis of the skin of the person being examined can be obtained using a fat-moisture sensing probe. At the same time, reference is made to FIGS. 4A and 4B. Fig. 4A shows a circuit diagram of a charge and discharge circuit for detecting fat and moisture at a skin site of a subject to be examined, and Fig. 4B shows a schematic representation of the charging and discharging cycles of the capacitors. As shown in Fig. 4A, on the circuit board of the receiving apparatus 1306, a pair of parallel-connected inductive resistors (Ra, Rb) and capacitors C are provided, which are connected to the inductive resistors (Ra, Rb) to thereby provide charging and discharging Forming discharge circuit. Here, the pair of parallel-connected inductive resistors (Ra, Rb) are connected to the fat-moisture detection probe 1301 to detect the resistance value caused thereby when the subject's skin contains fat and moisture. When the operator operates the skin analyzer 1, the pair of inductive resistors (Ra, Rb) connected in parallel, when the subject's skin contains fat and moisture, respectively detects the resistance value thereby generated. Subsequently, a charge and discharge circuit through the capacitors C and the inductive resistors (Ra, Rb) is formed. Here, Vcc is an external power supply. For example, a lithium battery 17 can provide the required power. When the operator uses the grease-moisture detecting means 130 of the skin analyzer 1 and then determines the resistance value generated by the inductive resistors (Ra, Rb), a charging operation on the capacitors C is made to be Vcc according to the resistance value of the inductive resistors (Ra, Rb) carried out.
    Fig. 4A shows an operation process. When the voltage Vc of the capacitors C does not reach one third of the voltage of the external supply voltage, the output voltage of the pin 3 is defined as a high signal (Hl). When the voltage Vc of the capacitors C reaches two thirds of the voltage of the external supply voltage, the output voltage of the pin 3 is defined as a low signal (LOW), thereby causing the capacitors C to discharge via the resistor Rb at the pin 4. In one example, a flip-flop (not shown) is disposed in pin 3 to output a high signal (HI) or a low signal (LOW) corresponding to the output voltage. At this time, when the fat-moisture detection probe 1301 detects fat and / or moisture on the skin of the person under examination, repeated charging and discharging operations are performed on the capacitors C, thereby obtaining charging and discharging cycles of the capacitors C, as shown in FIG 4B. Further, pin 2 is connected to the control capacitor C1 to reduce external noise in the charge and discharge circuit, wherein the capacitance value of the control capacitor C1 is about 0.1 pF and pin 1 is grounded, with pin 1 to the negative electrode of an external power supply connected is. Referring to Fig. 4B, the Vcc of the ordinate axis represents the voltage supplied by the external power supply, e.g. the voltage provided by the lithium battery 17. Since the supply voltage of the external power supply is a stable voltage, the charging and discharging cycles of the capacitors C have a regularity as shown in the lower figure in Fig. 4B, where T1 is the time required for the charging of the capacitors C, wherein T2 is the time required for the discharge of the capacitors C, and wherein the abscissa axis t is the charge and discharge cycle time of the capacitors C. When the capacitors C are discharged, an examined person's skin fat and moisture impedance signal may be generated and transmitted to the signal processing module 156 of the main circuit board 15 for processing, the relationship between the inductive resistors Ra, Rb and the charging resistor. and discharge cycles of the capacitors C is defined by the following formulas: T1 = 0.693 x (ra + rb) × C; T2 = 0.693 x rb x C and
    t = T1 + T2 = 1 / F where ra is the resistance value at the detection of the fat and moisture content of the examined person's skin by the inductive resistance Ra, rb being the resistance value at the detection of the fatigue by the inductive resistance Rb and moisture content of the examined person's skin, where C is the capacitance value of the capacitors C, and F is the charge and discharge frequency of the capacitors C.
    The signal processing module 156 of the main circuit board 15 can obtain a charge and discharge frequency F of the capacitors C according to the above relationship. Subsequently, the charge and discharge frequency F of the capacitors C is defined as a frequency signal of the fat and moisture analysis of the skin of the examined person, this frequency signal of fat and moisture analysis of the skin of the person being examined via the wireless transmission module 155 is sent to the receiving device 2. Subsequently, the app of the receiving device 2, an analysis of the frequency signal is performed by a frequency comparison, the frequency comparison based on the contents shown in Table 2. Table 2 shows that the frequency signal of the fat and moisture analysis is compared with reference fat and moisture values. By comparing the frequency signal of the fat and moisture analysis with the reference fat and moisture values, a moisture content and a fat content of the examined person's skin can be determined. Furthermore, the softness of the skin of the person being examined can be assessed by the moisture content and the fat content of the skin of the examined person. For example, the frequency range used to analyze the fat and moisture content of the subject's skin may be between 5 kHz and 120 kHz. However, the frequency range is not limited to the aforementioned frequency range of 5 kHz to 120 kHz.
    Table 2
    Frequency signal of the fat and 5 kHz to 30 kHz 31 kHz to 80 kHz 81 kHz to 120 kHz
    moisture analysis
    Fat and moisture values 0 to 40 44 to 52 53 to 65
    Skin Moisture Content Low Moisture Moisture High Moisture Content Salary
    Skin fat content very greasy moderately greasy slightly greasy
    Skin softness dry medium soft Furthermore, the skin analysis device 1 according to the invention can be used to obtain information about the skin condition of the examined person. Reference is made to FIG. 5A. FIG. 5A shows a flow chart of a corresponding mode of operation of the skin analysis device according to the invention. First, as shown in step S1, the operator first starts the skin analyzer 1. For example, the operator presses the power switch 154, whereby the LED lamps 111 emitting white light, the lens module 14, and the main circuit board 15 are started be supplied. Subsequently, as shown in step S2, the operator can perform a connection test for the skin analysis device 1 and the reception device 2 in order to check whether the wireless transmission module 155 of the skin analysis device 1 is connected to the app of the reception device 2. The app can be an app suitable for mobile devices (mobile application). Then, as shown in step S3, to perform a skin analysis, the operator aligns the opening 21 of the skin analyzer 1 with the subject's skin to be examined (eg, on the facial skin), at which time an image of the examined person's skin is obtained Light of the LED lamps 111, which emit white light, and can be picked up by the camera unit 141 of the objective module 14, thereby obtaining a polarized light signal, the polarized light signal being further transmitted to the signal processing module 156 in order to make it To process image of the skin of the examined person. Subsequently, the pre-image of the skin of the examined person is transmitted to the receiving device 2 by the wireless transmission module 155, and thereafter the skin of the examined person is displayed via the display (not shown) of the receiving device 2. Subsequently, as shown in step S4, the operator decides whether an analysis of the skin condition of the person being examined should be performed. For example, when the examined person views his or her skin via the display of the receiving device 2 and decides that he wishes to perform a skin analysis, the operator can press the recording control switch 153 (ie, the record button) to take a picture, thereby acquiring the skin analyzer 1 Before-picture of the skin of the examined person can be obtained. Subsequently, the before-image of the skin of the examined person is analyzed by the app of the receiving device 2 in order to obtain the corresponding analysis results. Finally, these analysis results are displayed by means of the receiving device 2 of the examined person and / or the operator. In this way, the examined person and / or the operator can get an accurate picture of the condition of the skin at the appropriate place. The analysis results can be represented for example in the form of an analysis index.
    Reference is also made at the same time to Figs. 5B and 6A to 6F. Fig. 5B shows a flow chart of the pre-image skin analysis method of the examined person, and Figs. 6A to 6F show schematic contrast images of the skin of a subject obtained by using the analysis method shown in Fig. 5B. FIG. 6A shows a schematic representation of the pore contrast of the image of the subject's skin to be examined, FIG. 6B shows a schematic representation of the texture contrast of the image of the subject's skin to be examined, FIG. 6C shows a schematic representation of the contrast of the image of the subject Fig. 6D shows a schematic representation of the wrinkle contrast of the image of the subject's skin to be examined, Fig. 6E shows a schematic representation of a fluorescence response of a metal to the skin surface by UV detection, and Fig. 6F shows a schematic representation of the UV light detection of clogged pores and cornification. Figs. 6A to 6F illustrate the images of the test subject's skin site obtained by processing with the analysis method illustrated in Fig. 5B (upper images of Figs. 6A to 6D) and black and white contrast images of the subject's skin site to be examined (lower Figs 6A-6D), wherein in the black-and-white contrast images the black areas after increasing the contrast represent areas containing skin patches, skin textures, pores or wrinkles, and the white areas are the normal areas of the skin represent. As shown in step S41, after the receiving device 2 has received the pre-image of the examined person's skin sent from the wireless transmission module 155, the image of the receiving device 2 is preprocessed by the app. For example, an image section is selected or noise removal is performed to thereby obtain a preprocessed image of the examined skin site of the subject, thereby facilitating the later analysis steps. Subsequently, as shown in step S42, the contrast of the image of the examined skin site of the subject is enhanced by the improvement of color contrast. For example, spots, textures, pores, or wrinkles in the image of the examined skin site are enhanced as compared with the normal skin, thereby obtaining an image of the examined skin site of the higher contrast subject. Subsequently, as shown in step S43, the higher contrast image of the examined skin site of the subject is classified by the app according to the analysis target, with possible analysis objectives relating to the occurrence of skin defects and skin texture. For example, skin defects are defined as patches and pores, where the skin texture is defined by wrinkles and textures. Subsequently, as shown in step S44, a black-and-white contrast image is obtained by post-processing the higher contrast image of the examined skin area of the subject, the post-processing comprising image edge detection and image color layer analysis, using the Canny image edge detection algorithm And the algorithm for analyzing the image color layers may be, but not limited to, the Fuzzy C-Means algorithm. By means of the image app, a statistic for the black areas in the black-and-white contrast image can be carried out, wherein the results of the statistics of the examined person and the operator can be displayed by means of the receiving device 2 in the form of an analysis index. For example, when the skin pore size analysis performed by the app on a skin site of the subject examined shows the proportion of black areas in the black-and-white contrast image obtained by the analysis method to be 20%, the subject and the operator become an analysis result having a pore analysis index of 20 displayed. In the same way, by using the analysis method, the skin analyzer 1 can also obtain various other information concerning the skin condition of the subject, providing it as a basis for subsequent skin consultation performed with the person being examined. According to the upper illustration of FIG. 6A, it is obvious that the pore sizes and pore positions of the examined skin area of the test subject can be determined exactly by means of the skin analyzer 1 according to the invention, the pore sizes and pore positions being investigated in combination with the lower image in FIG Skin spot of the subject are even more visible. According to the upper illustration in FIG. 6B, the texture sizes and texture positions of the examined skin area of the test subject can be determined exactly by means of the skin analysis device 1 according to the invention, wherein in combination with the lower image in FIG. 6B the texture sizes and texture positions at the examined skin site of the test subject become even clearer are visible. According to the upper figure in Fig. 6C, the spot sizes and patch positions of the examined skin area of the subject can be accurately determined by the skin analyzer 1 according to the present invention, and in combination with the lower figure in Fig. 6C, the spot sizes and patch positions of the examined skin area of the subject are more clearly visible , According to the upper illustration in FIG. 6D, the wrinkle sizes and wrinkle positions of the examined skin area of the test subject can be determined exactly by means of the skin analyzer 1 according to the invention, the wrinkle sizes and wrinkle positions of the examined skin area of the subject being more clearly visible in combination with the lower image in FIG. 6D , Further, as shown in FIG. 6E, a fluorescence reaction of a metal on the skin surface by means of the skin analyzer 1 of the present invention can be clearly imaged by irradiation with UV light having a specific wavelength. Therefore, the skin analyzer 1 can also be used to detect whether metal components are present on the skin surface of the person being examined. Furthermore, as shown in Fig. 6F, acne and bacterial accumulations in the skin pores can be clearly shown in different colors by the ultraviolet light irradiation apparatus of the present invention by irradiation with ultraviolet light having a specific wavelength. Therefore, the skin analyzer 1 can be used to check if the skin pores are clean.
    In order to make it possible to determine the fat and moisture content at the examined skin site of a subject and furthermore the softness of the skin by means of the skin analysis device 1 according to the invention, it is further possible
    权利要求:
    Claims (4)
    [1]
    A skin analyzer (1) comprising: an LED light panel (11), wherein a plurality of LED lamps (111) that emit white light and a plurality of LED lamps (112) that emit UV light are attached to the LED Light panel (11) are arranged to provide the required for the use of the skin analyzer detection light, a first polarizer (12) which is arranged on the LED light panel (11), wherein the first polarizer (12) serves to to filter out the scattered light reflected from the projection of the detection light onto a skin site of the person being examined, thereby obtaining a polarized light signal, a lens module (14) having a camera unit (141), a terminal thereof being connected to a terminal of the LED light panel (11) wherein the lens module is for receiving the polarized light signal and for transmitting a resultant electrical signal to the main circuit board (15), the lens module (14) having a recording control scarf ter (153), by which the operation of the lens module (14) is controlled, a main circuit board (15), a terminal of which is connected to a terminal of the lens module (14), wherein a light control switch (152), a recording control switch ( 153), a power switch (154), a wireless communication transmission module (155) and a signal processing module (156) are disposed on the main circuit board (15), the signal processing module (156) receiving the electrical signals communicated from the lens module (14), a lower cover (18), the lower cover having a receiving space (181), wherein the receiving space (181) the LED light panel (11), the lens module (14), the main circuit board (15). and a loading panel (16) and an upper cover (19), wherein the upper cover (19) is connected to the lower cover (18), wherein a plurality of keys (192) on the upper Abd are arranged (19), wherein the keys (192) with the light control switch (152), the recording control switch (153) and the power switch (154) are connected.
    [2]
    The skin analyzer (1) of claim 1, further comprising an end cover portion (120), the end cover portion being disposed at the rear ends of the top cover (19) and the bottom cover (18), the end cover portion (120) defining an end cover trim ring (1201), an end cover (1202), and an end cover seal ring (1203), wherein the end cover seal ring (1203) is disposed on the end cover (1202), one end of the end cover (1202) being integral with the end cover trim ring (1202). 1201) is connected.
    [3]
    The skin analyzer (1) according to claim 1, wherein a plurality of through holes (121) tuned to the LED lamps (111) emitting white light are provided at the periphery of the first polarizer (12).
    [4]
    The skin analyzer (1) of claim 1, further comprising a second polarizer (13), the second polarizer (13) being disposed on a side of the first polarizer (12) facing the skin site to be examined, whereby the first polarizer (12) and the second polarizer (13) are superposed with each other.
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    同族专利:
    公开号 | 公开日
    TWI639137B|2018-10-21|
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    法律状态:
    2021-01-15| NV| New agent|Representative=s name: LIFETRONS SCHWEIZ AG, CH |
    优先权:
    申请号 | 申请日 | 专利标题
    TW106114089A|TWI639137B|2017-04-27|2017-04-27|Skin detection device and the method therefor|
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