KR100705743B1 - Skin measurement apparatus - Google Patents

Abstract

The present invention relates to a skin measuring apparatus, comprising: a first optical fiber transmission channel having a mutually separated optical transmission path, a probe having a second optical fiber transmission channel, and light emitted through the first optical fiber transmission channel to a main body connected to the probe A light source to detect the light emitted through the first optical fiber transmission channel and reflected from the measurement object and then transmitted through the second optical fiber transmission channel to convert the light into an electrical signal, and a driver to control the driving of the light source; A mode selector configured to select one of a plurality of measurement modes including a display unit for displaying display information, an oil mode for measuring skin oil content, and a whitening mode for measuring skin color, and a mode selector The driver is controlled in accordance with the measurement mode selected by the controller, and the signal output from the photodetector is compared with the reference data recorded in the lookup table. A controller for calculating a measured value corresponding to the memory card and displaying the calculated measured value through a display unit. According to such a skin measuring apparatus, the structure is simple and provides the advantage of measuring and displaying all the information on the moisture, oil content and color of the skin using a single light source.

Description

Skin measurement apparatus {skin measurement apparatus}

1 is a perspective view showing a skin measuring apparatus according to the present invention,

2 is a view showing the components of the skin measurement apparatus of FIG.

<Description of Symbols for Main Parts of Drawings>

110: main body 120: light source

131: first photodetector 132: second photodetector

141: control unit 144: mode selection unit

151: first optical fiber transmitter 152: second optical fiber transmitter

The present invention relates to a skin measuring apparatus, and more particularly, to a skin measuring apparatus capable of measuring the color, oil and moisture content of skin.

In general, human skin has a variety of forms. Therefore, in case of makeup, it is necessary to know the exact information about their skin condition because it is possible to maintain healthy and beautiful skin only by selecting cosmetics suitable for their skin condition.

According to these requirements, various devices have been developed to measure skin moisture content and skin color.

Korean Utility Model Registration No. 20-0409701 discloses a skin humidity measuring device that can measure the change in electrical impedance according to the moisture content of the skin through the humidity sensor. This method of measuring the skin humidity utilizes a property in which the surface of the skin has electrical conductivity when moisture is present because a large amount of electrolytes such as salts and amino acids are contained in the stratum corneum. However, this method is possible to measure the skin moisture, but there is a disadvantage that can not measure the skin color or oil content.

On the other hand, Korean Patent Laid-Open No. 2002-0022266 discloses a skin measurement system that can measure the condition of the skin from the image captured using a video microscope. However, a system capable of analyzing skin tissue by such an imaging method has a disadvantage in that the configuration is complicated and expensive, so it can only be limitedly used in some large hospitals.

SUMMARY OF THE INVENTION The present invention has been made to improve the above problems, and its object is to provide a skin measuring apparatus which is simple in structure and can acquire characteristic information on skin.

In order to achieve the above object, the skin measurement apparatus according to the present invention includes a main body, a probe connected to the main body, and the probe has a first optical fiber transmitter and a second optical fiber transmitter having separate optical transmission paths. The main body includes a light source for emitting light through the first optical fiber transmission body; A light detector which detects the light transmitted through the second optical fiber transmitter after being emitted through the first optical fiber transmitter and reflected from the measurement object, and converts the light into an electrical signal; A driving unit controlling driving of the light source; A display unit for displaying display information; A mode selection unit configured to select any one of a plurality of measurement modes including an oily mode for measuring the oil content of the skin and a whitening mode for measuring the color of the skin; The driving unit is controlled according to the measurement mode selected by the mode selection unit, and the measured value corresponding to the selected mode is calculated by comparing the signal output from the photodetector with comparison reference data recorded in a lookup table, and the calculated measurement. And a controller for displaying a value through the display unit.

Preferably, the light detector comprises: a dichroic mirror arranged to receive light incident from the second optical fiber transmitter; A first photodetector for detecting light transmitted through the dichroic mirror; The dichroic mirror is provided with a second photodetector for detecting light reflected by a path different from the incident path, wherein the mode selection unit supports selecting a moisturizing mode for measuring moisture content of the skin, and the controller The moisture content is calculated from the signal output from the second photodetector in the moisturizing mode, and the oil content and skin color are calculated from the signal output from the first photodetector in the oily mode and the whitening mode.

Preferably, the light source is a UV light emitting diode that emits ultraviolet light is applied, the dichroic mirror is a light of 430nm is incident to the second photodetector, the light outside the 430nm is incident to the first photodetector What can be applied.

In addition, the controller controls the driving unit so that the amount of current applied to the light source at the time of the whitening board is smaller than at the oil mode.

More preferably, the control unit controls the driving unit to drive the light source on / off at a set period in order to remove the influence of the disturbance light including natural light in the light detected by the light detection unit, the light of the light source of the light incident from the The measured value is calculated by using the optical signal corresponding to the driving period.

In addition, a groove in which a predetermined length is drawn inward is formed on an upper surface of the probe, and a lens is provided in the groove to face the first and second optical fiber transmitters.

Hereinafter, a skin measuring apparatus according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in more detail.

1 is a perspective view showing a skin measuring apparatus according to the present invention, Figure 2 is a view showing the components of the skin measuring apparatus of FIG.

1 and 2, the skin measuring apparatus 100 includes a main body 110 and a probe 150.

The probe 150 is configured to be detachable from the main body 110.

The probe 150 includes a first optical fiber transmitter 151, a second optical fiber transmitter 156, and a housing 158.

The first optical fiber transmitter 151 is provided with a connector 152 at one end so as to be connected to the first connection terminal provided in the main body 110, and the light emitted from the main body 110 through the first connection terminal. It has a structure with an optical fiber that can transmit. A predetermined length portion from the end of the first optical fiber transmission body 151 is mounted to be accommodated in the housing 158.

The second optical fiber transmitter 156 is provided with a connector 157 at one end thereof so as to be connected to a second connection terminal provided at the main body 110, and transmits the light incident through the other end to the light detecting unit in the main body 110. It is supposed to be.

The housing 158 is configured to cover the first optical fiber transmitter 151 and the second optical fiber transmitter 156 by a predetermined length.

The upper surface of the housing 158 may be transmitted through the light emitted from the end of the first optical fiber transmitter 151 to be emitted to the outside, and the light reflected from the measurement object is to terminate the end of the second optical fiber transmitter 156. It may be formed to be incident through.

Preferably, the groove 158a is inserted into the upper surface of the housing 158 in a predetermined depth so as to constantly guide the separation distance between the measurement object and the ends of the first and second optical fiber transmitters 151 and 156. Is provided, and the lens 159 is attached to the bottom surface of the groove. In addition, ends of the first and second optical fiber transmitters 151 and 156 are coupled in the housing 158 to face the lens.

Therefore, when the measurement object is in contact with the upper surface of the housing, the distance between the end of the first and second optical fiber transmitters 151 and 156 and the measurement object is kept constant by the depth of the groove 158a of the housing 158. You can.

The lens 159 preferably applies a height correcting lens having a high transmittance from the ultraviolet region to the visible region.

For example, the housing 158 may be formed of a Teflon material, and the outer circumferential surface may be applied to a black material or black so as to block external light.

The main body 110 is provided with a light source 120, first and second photodetectors 131 and 132, a driver 125, a controller 141, a mode selector 144, and a display 146.

The light source 120 is preferably an ultraviolet light emitting diode that emits ultraviolet light. More preferably, the light source 120 is a light emitting diode that emits light of 360nm is applied.

The driver 125 is controlled by the controller 141 to control the amount of current applied to the light source 125.

The photodetector includes a first photodetector 131, a second photodetector 132, and a dichroic mirror 135.

The first photodetector 131 is installed to detect light transmitted from the second optical fiber transmitter 156 and transmitted through the dichroic mirror 135.

The second photodetector 132 is installed to detect the light transmitted from the second optical fiber transmitter 156 and reflected at a different angle from the path incident on the dichroic mirror 135.

The dichroic mirror 135 reflects the light of the set first wavelength band in a path different from the incident path, and transmits light outside the first wavelength band. Preferably, the dichroic mirror 135 reflects 430 nm of the incident light and enters the second photodetector 132, and transmits light outside the 430 nm to enter the first photodetector 131. That is.

Meanwhile, an amplifier (not shown) for amplifying the signal output from the photodetectors 131 and 132 and a filter (not shown) for removing noise from the amplified signal may be further provided.

Reference numerals 127, 136, and 137 denote focusing lenses.

In the photodetector, the first photodetector 131 is applied to the oil mode and the whitening mode, and the second photodetector 132 is applied to the moisturizing mode.

Here, in the moisturizing mode, when ultraviolet light emitted from the light source 120 is incident on the skin of the subject through the first optical fiber transmitter 151, the skin responds to the incident ultraviolet light according to the moisture content of the skin of the subject. The principle that the color emitted from the secondary light from the second is used. That is, the amount of light purple light of 430 nm emitted from the skin varies according to the characteristics of the skin tissue according to the moisture content of the skin. Therefore, the moisture content of the skin can be measured inversely according to the amount of light of the 430 nm wavelength emitted from the skin.

In more detail, dry skin has a small amount of sebum secretion, so the skin surface is dry, glossy, and the skin texture is very thin and delicate. In particular, dry skin has less moisture and oil, resulting in white keratin and externally rough and glossy. Such dry skin is caused by internal factors, namely, lack of moisture in the dermis, resulting in disruption of collagen and elastin production along with fibroblast damage. In addition, the skin tissue is thin and delicate, capillaries appear on the skin surface. Therefore, erythema occurs when skin is in contact with environmental factors such as UV, cold, and heat. Using this phenomenon, when the ultraviolet light of 360 nm is emitted to the skin to be examined, the light around the purple 430 nm is detected by the thinned skin tissue in the dry skin, and the amount of light in the 430 nn band is changed depending on the moisture content.

The display unit 146 is controlled by the control unit 141 to display the display information.

The mode selector 144 may select one of an oily mode for measuring the oil content of the skin to be measured, a moisturizing mode for measuring the moisture content of the skin, and a whitening mode for measuring the color of the skin. In the illustrated example, the mode selection unit 144 is able to select any one of the measurement modes by position manipulation of the mode selection key 144a.

The controller includes a controller 141 and a memory 142.

The memory 142 records comparative reference data graded into a plurality of grades to determine which level the signal output from the corresponding photodetectors 131 and 132 corresponds to each of the moisturizing mode, the whitening mode, and the oily mode. Lookup table (LUT) is provided.

The controller 141 controls the driver 125 according to the measurement mode selected by the mode selector 144, and uses the reference data of the lookup table 142a and the signal output from the photodetectors 131 and 132. The measured value corresponding to the corresponding measurement mode is calculated, and the calculated measured value is displayed on the display unit 146.

Preferably, the control unit 141 is a driving unit 125 so that the light source 120 is driven on / off at a set cycle in order to remove the influence of disturbance light, such as natural light, light emitted from the light, among the light detectors 131 and 132 detected. ), And the measured value is calculated using the output corresponding to the driving period of the light source 120 in the light input to the photodetectors 131 and 132.

The on / off driving period of the light source 120 is driven at 800 to 900 Hz, more preferably at 840 Hz.

Hereinafter, a method of measuring using such a skin measuring apparatus will be described.

In the oily mode, oil, that is, normal sebum, is used to remove the oil by rubbing the face oil removal film on the skin of the subject using a face oil removal film whose transmittance varies depending on the amount of oil contained in the skin. Wipe it off. Here, the film for removing facial oil may be applied to that disclosed in Korean Laid-open Patent No. 2003-0001473.

Next, the mode selection key 144a of the main body 110 is selected as the oily mode while the face oil removing film is positioned to face the housing upper surface 158 of the probe 150, and the control unit 141 operates. Compares the oil content corresponding to the amount of light detected by the first photodetector 131 with the comparison reference data recorded in the lookup table 142 to determine which level it belongs to. Here, the comparison reference data recorded in the lookup table 142a is classified into 100 classes of light quantity measured by the above-described oil content measuring method using a population of hundreds or thousands, and the light quantity value range corresponding to each classified class is determined. It is written down.

Therefore, the controller 141 determines the grade to which the oil content measured by the first photodetector 131 belongs using the reference data recorded in the lookup table 142a, and displays the level value corresponding to the determined grade. ).

In addition, in the whitening mode, the probe 150 is measured in a state close to the skin of the measurement target, and the controller 141 compares the amount of light received through the first photodetector 131 with the comparison reference recorded in the lookup table 142a. The data is compared and the level corresponding to the skin color is displayed.

Here, the comparative reference data for the skin color recorded in the lookup table 142a is a skin color, that is, a large number of light colors measured for a population selected from a large number of people as described above, from dark brown to white in the case of Asian dragons. The light quantity value corresponding to the grade classified into the grade of is recorded.

Meanwhile, even in the moisturizing mode, the probe 150 is measured in a state close to the skin of the measurement target, and the control unit 141 previously compares the signal output from the second photodetector 132 by the method described above with reference data. Is determined from the comparison reference data of the recorded lookup table 142a, and the level corresponding to the determined water content is displayed on the display unit 146. FIG.

As described above, according to the skin measurement apparatus according to the present invention, the structure is simple and provides an advantage of measuring and displaying information on moisture, oil content, and color of the skin using a single light source.

Claims (6)

A main body and a probe connected to the main body, The probe includes a first optical fiber transmitter and a second optical fiber transmitter having optical paths separated from each other, The main body A light source emitting light through the first optical fiber transmitter; A light detector which detects the light transmitted through the second optical fiber transmitter after being emitted through the first optical fiber transmitter and reflected from the measurement object, and converts the light into an electrical signal; A driving unit controlling driving of the light source; A display unit for displaying display information; A mode selection unit configured to select any one of a plurality of measurement modes including an oily mode for measuring the oil content of the skin and a whitening mode for measuring the color of the skin; The driving unit is controlled according to the measurement mode selected by the mode selection unit, and the measured value corresponding to the selected mode is calculated by comparing the signal output from the photodetector with comparison reference data recorded in a lookup table, and the calculated measurement. And a controller for displaying a value through the display unit. The method of claim 1, wherein the photodetector A dichroic mirror arranged to receive light incident from the second optical fiber transmitter; A first photodetector for detecting light transmitted through the dichroic mirror; A second photodetector configured to detect light reflected by a path different from the incident path in the dichroic mirror; The mode selector supports selecting a moisturizing mode for measuring the moisture content of the skin. The controller calculates the moisture content from the signal output from the second photodetector in the moisturizing mode, and calculates the oil content and skin color from the signal output from the first photodetector in the oily mode and the whitening mode. Skin measuring device characterized in that. According to claim 2, wherein the light source is an ultraviolet light emitting diode that emits ultraviolet light is applied, The dichroic mirror is a skin measuring device, characterized in that the light of 430nm is incident to the second photodetector, the light out of 430nm can be incident to the first photodetector. The skin measurement apparatus according to claim 2, wherein the controller controls the driving unit so that the amount of current applied to the light source is smaller at the time of the whitening board than at the oil mode. According to claim 1, wherein the control unit controls the drive unit to drive the light source on / off at a set period in order to remove the influence of disturbance light including natural light in the light detected by the light detection unit, the light of the incident light from the light detection unit A skin measuring apparatus, comprising: calculating a measured value by using an optical signal corresponding to a driving period of a light source. The method of claim 1, wherein a groove having a predetermined length introduced into the upper surface of the upper surface in contact with the measuring object of the probe, the lens is provided in the groove to face the first and second optical fiber transmitters. Skin measuring device.

Images