KR101928057B1 - Apparatus for calculating vitamin d compose amount and mehtod for controlling the same, and lighting system for inducing vitamin d synthesis in body - Google Patents

Abstract

The present invention relates to a vitamin D synthesis amount determination apparatus, wherein the vitamin D synthesis amount determination apparatus comprises a storage unit for storing the amount of ultraviolet B amount, a storage unit for storing the amount of ultraviolet B amount, D synthesis amount and comparing the calculated amount of vitamin D synthesis with a required daily vitamin D level to output a vitamin D attained state; and an activity control unit connected to the operation control unit, And outputs an output signal.

Description

TECHNICAL FIELD [0001] The present invention relates to a vitamin D synthesis amount determination apparatus, a control method thereof, and a system for inducing synthesis of a vitamin D. [0002]

The present invention relates to a vitamin D synthesis amount determination apparatus, a control method thereof, and a system for inducing synthesis of a vitamin D body.

In general, vitamin D (vitamin D) is one of the fat-soluble vitamins, liver oil, tuna, sardines, milk, egg yolk and is said to be a lot.

When vitamin D is not consumed through food, when the sunlight is irradiated for a certain time, 7-dehydrocholesterol of the subcutaneous layer is converted into vitamin D by the ultraviolet rays contained in sunlight, that is, Vitamin D is synthesized in the body.

However, due to the development of civilization and changes in life patterns, most modern humans have less time to be exposed to sunlight due to increased residence time in the room, so that the amount of vitamin D that can be synthesized through sunlight is very small There are many cases.

Also, intake of vitamin D through food is not easy. Vitamin D deficiency is causing the phenomenon.

In particular, vitamin D deficiency, an essential nutrient for life support, is becoming a serious health problem worldwide due to the increase in the elderly population and the obese population.

Therefore, people who are deficient in vitamin D should supplement their deficient vitamin D by eating a supplement, but many people are not able to consume vitamin D because of economic reasons and lack of time.

In addition, when vitamin D is consumed by sunlight through outdoor activities, the amount of vitamin D synthesized at present can not be known accurately.

Therefore, the amount of vitamin D synthesized does not reach the recommended daily dose, or conversely, exceeds the daily recommended amount. When exposed to sunlight for a long time, it causes health problems such as skin cancer.

Korean Patent Application No. 10-2013-0152777 filed on Dec. 10, 2013, entitled " Illumination System for Inducing Synthesis of Vitamin D in the Body & Korean Patent Publication No. 10-2006-0110025 (published on October 24, 2016, entitled "Lighting Device and Controller System for Ultraviolet Radiation Sterilization")

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a method for accurately and rapidly confirming the amount of vitamin D produced.

The system for inducing the in vitro synthesis of vitamin D according to one aspect of the present invention calculates the amount of the user's vitamin D synthesis relative to the amount of the ultraviolet ray B determined using the amount of ultraviolet ray B determined, And a vitamin D synthesis amount determination device that determines the attained state of vitamin D by comparing the amount of vitamin D required and determines that the ultraviolet ray B can be irradiated to the user if the amount of synthesized vitamin D does not satisfy the required daily amount of vitamin D.

The vitamin D body synthesis induction system according to the above feature includes an ultraviolet ray B light source and the ultraviolet ray B light source is turned on by the control operation of the vitamin D synthesis amount determination apparatus or by the user to irradiate the ultraviolet ray B to the user And may further comprise an ultraviolet B illuminator that allows vitamin D synthesis to occur.

The daily vitamin D requirement of the user is preferably determined according to the age and sex of the user.

According to another aspect of the present invention, there is provided an apparatus for determining the amount of vitamin D, which comprises calculating a quantity of vitamin D synthesis using a storage unit storing the amount of ultraviolet B amount and a quantity of the ultraviolet B amount stored in the storage unit And an operation control unit for comparing the amount of vitamin D synthesized with the amount of vitamin D required per day and outputting the vitamin D achievement state.

It is preferable that the operation control unit judges the quantity of ultraviolet ray B plate quantity using externally applied ultraviolet ray B quantity sensing data and stores it in the storage unit.

The vitamin D synthesis amount determination apparatus may further include an ultraviolet B amount sensing unit connected to the operation control unit, wherein the operation control unit controls the ultraviolet B amount sensing unit using the sensing signal applied from the ultraviolet B amount sensing unit, And store it in the storage unit.

It is preferable that the storage unit further stores the minimum erythema amount, ultraviolet ray exposure time, and exposed area for each skin type, and the operation control unit may use the ultraviolet ray B amount, the minimum erythema amount per skin type, the ultraviolet ray exposure time, The amount of vitamin D synthesis can be calculated.

The vitamin D synthesis amount determination apparatus according to the above feature may further include an output unit connected to the operation control unit and outputting the vitamin D achievement state output from the operation control unit.

The operation control unit may determine an ultraviolet ray index using externally applied ultraviolet ray exponent detection data.

The vitamin D synthesis amount determination apparatus according to the above feature may further include an ultraviolet ray exponent detection unit connected to the operation control unit, and the operation control unit may detect the ultraviolet ray index using the sensed signal applied from the ultraviolet ray exponent detection unit .

 The operation control unit may determine a level to which the determined ultraviolet ray index belongs, and output a user recommendation message corresponding to the determined level and the determined level to the output unit.

The operation control unit may calculate the ultraviolet ray B dose amount using the determined value of the ultraviolet ray index.

The operation control unit may determine the age and gender of the user stored in the storage unit, and read the required amount of vitamin D corresponding to the determined age and gender from the storage unit.

The operation control unit may output a control signal for turning on the ultraviolet B light source to the ultraviolet B illuminator if the calculated amount of the synthesized vitamin D does not reach the required amount of vitamin per day.

The vitamin D synthesis amount determination apparatus according to the above feature may include at least one of an ultraviolet ray B amount sensing unit and an ultraviolet ray exponent sensing unit and may detect an amount of ultraviolet ray B output from at least one of the ultraviolet ray amount sensing unit and the ultraviolet ray index sensing unit And an ultraviolet ray information detector for transmitting data and ultraviolet ray exponent detection data to the operation control unit. The operation control unit may calculate the ultraviolet ray B saturation amount using the ultraviolet ray detection data or the ultraviolet ray exponent detection data have.

A control method for a vitamin D synthesis amount determining apparatus according to another aspect of the present invention comprises the steps of calculating the amount of vitamin D synthesis using the amount of ultraviolet B amount determined and calculating the amount of vitamin D required per day And comparing the vitamin synthesis amount with the daily vitamin D requirement to output the vitamin D achievement state to the output unit.

 The control method of the vitamin D synthesis amount determination apparatus according to the above feature may further comprise the steps of: determining an ultraviolet ray index using ultraviolet ray index data corresponding to an ultraviolet ray index detection signal or an ultraviolet ray index detection signal; and outputting the determined ultraviolet ray index to the output unit Step < / RTI >

The control method of the vitamin D synthesis amount determination apparatus according to the above feature may further comprise the steps of: determining a level to which the ultraviolet ray index determined among the plurality of levels stored in the storage section belongs; reading a user recommendation message corresponding to the determined level from the storage section And outputting the level of the ultraviolet ray index and the user recommendation message to the output unit.

The quantification of the ultraviolet ray B plate can be calculated using the value of the ultraviolet ray index determined above.

The control method of a vitamin D synthesis amount determining device according to the above feature may further comprise the steps of: determining whether the calculated amount of vitamin D synthesis has reached the required daily vitamin amount; and if the calculated amount of synthesized vitamin D does not reach the required daily vitamin amount, And outputting a control signal for turning on the ultraviolet B light source to the B illuminating device.

According to these characteristics, since the achievement rate of vitamin D synthesized through ultraviolet rays can be accurately known, the user can take action to supplement the insufficient amount in comparison with the daily vitamin D requirement, .

In addition, it is possible to confirm the accurate ultraviolet ray index of the position where the current user is located, and also to easily confirm the ultraviolet ray index level of the position where the user is located, so that the outdoor activity is determined based on the accurate ultraviolet ray index.

If the amount of vitamin D synthesized through ultraviolet ray B does not reach the required amount of vitamin D per day, the user operates the ultraviolet ray B light source in the room where the user is located, so that insufficient vitamin D synthesis operation is performed in the room.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic block diagram of a system for inducing synthesis of vitamin D in the present invention. FIG.
2 is a block diagram of a vitamin D in vivo synthesis induction system according to an embodiment of the present invention.
FIG. 3 is a schematic block diagram of the ultraviolet information sensing apparatus shown in FIG. 2. FIG.
Fig. 4 is a schematic block diagram of the vitamin D determination device shown in Fig. 2; Fig.
5 to 7 are operational flowcharts of a vitamin D determination device according to an embodiment of the present invention.
FIG. 8 is an example of a user information input window output to the vitamin D determination device of the in vitro synthesis system for vitamin D in accordance with an embodiment of the present invention.
9 is an example of an output screen of a determination result when the ultraviolet ray index is at a low level in a vitamin D determination device of a system for inducing synthesis of a vitamin D complex in accordance with one embodiment of the present invention.
10 is an example of an output screen of a determination result when the ultraviolet ray index is at a normal level in a vitamin D determination device of a system for inducing an intra-vitamin D synthesis in accordance with an embodiment of the present invention.
FIG. 11 is an example of an output screen of a determination result when the ultraviolet ray index is at a high level in a vitamin D determination device of a system for inducing intracellular vitamin D in accordance with an embodiment of the present invention.
12 is an example of an output screen of a determination result when the ultraviolet ray index is at a very high level in a vitamin D determination device of a system for inducing intravitreal vitamin D in accordance with an embodiment of the present invention.
FIG. 13 is an example of an output screen of a determination result when the ultraviolet ray index is at a critical level in a vitamin D determination device of a system for inducing intravitreal vitamin D in accordance with an embodiment of the present invention.
14 is an example of a setting window for adjusting the state of the ultraviolet B illumination device output from the vitamin D determination device in the vitamin D body synthesis induction system according to an embodiment of the present invention.
FIG. 15 is an image of a screen for outputting the ultraviolet ray index and the amount of vitamin D synthesis in a graph form in a vitamin D determination device of a system for inducing intracellular vitamin D in accordance with an embodiment of the present invention.
16 is a block diagram of a vitamin D body induction system according to another embodiment of the present invention.
FIG. 17 is a schematic block diagram of the vitamin D determination device shown in FIG. 16; FIG.
18 and 19 are operational flowcharts of a vitamin D determination device according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, but it should be understood that there may be other elements in between do. On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

Hereinafter, a vitamin D synthesis amount determination apparatus, a control method thereof, and a vitamin D in situ synthesis induction system according to an embodiment of the present invention will be described with reference to the accompanying drawings.

First, the vitamin D body synthesis induction system of the present invention will be described.

As shown in FIG. 1, the vitamin D body synthesis induction system of the present invention includes an ultraviolet information sensing device 110, a mobile device 120 that communicates with the ultraviolet information sensing device 110 through a communication network NT, A light source driving apparatus 130 connected to the communication network NT and a light source 140 connected to the light source driving apparatus 130. The light source driving apparatus 130 is connected to the ultraviolet information sensing apparatus 110 through the communication network NT, Respectively.

At this time, the light source driving device 130 and the light source 140 constitute the lighting device 150.

The ultraviolet information sensing apparatus 110 must be present with the user to control the lighting operation of the lighting apparatus 150 according to the position of the user using the present system to supply illumination to the user.

Accordingly, the ultraviolet information sensing device 110 is a wearable sensor unit that can be attached to a user's wrist, necklace, clothes, ring, or the like.

The mobile device 120 inputs various kinds of information required for the operation control of the lighting device 150 from the user in consideration of the user's physical characteristics such as the user's key, age, weight, , Generates a control signal for controlling the operation of the illuminating device 150 based on the input information, and transmits the control signal to the illuminating device 150 using the communication network NT.

Although the mobile device 120 is provided with an application capable of controlling the operation of the lighting device 150, an application capable of controlling the operation of the lighting device 150 in some cases must always be a mobile device 120 And may be installed in an ultraviolet information sensing device 110 or a light source driving device 130 or a separate controller (not shown), and may be connected to a light source 140 Can be controlled.

In this embodiment, the ultraviolet information sensing device 110 and the mobile device 120 are separate devices. However, the ultraviolet information sensing device 110 is not limited to this, and the ultraviolet information sensing device 110 may be located in the mobile device 120, The device 110 and the mobile device 120 may be a single device.

The light source 140 is turned off according to the light source driving signal applied from the light source driving device 130 and outputs ultraviolet (UV) light.

The light source 140 may also provide illumination and color temperature to the user through a light source in the visible light wavelength band.

UV-A (wavelength: 400 nm to 315 nm), ultraviolet-B (UV-B) (wavelength: 315 nm to 280 nm) and ultraviolet-C (UV- , Which is known as ultraviolet-B, which can produce vitamin D in the body and does not adversely affect the human body due to ultraviolet rays.

The synthesis of vitamin D in the human body is also done through food. The amount of vitamin D synthesized through food is about 100 IU (International Unit, about 1 IU = 0.025 μg for vitamin D), about 20% of the daily requirement.

On the other hand, vitamin D synthesized in the human body is also synthesized by irradiation of ultraviolet light (especially ultraviolet ray -B) contained in sunlight, and vitamin D corresponding to the remaining 80% .

However, ultraviolet-B does not pass through glass or fiber, and even in the case of cold winter or above 35 degrees of sunlight, there is a lack of ultraviolet-B in the sunlight,

Therefore, it is preferable that the light source 140 of the present invention can perform vitamin D synthesis in the human body by using a light source (for example, UV-LED) generating ultraviolet-B.

The light source driving device 130 or the mobile device 120 stores data on the intensity of the UV-B wavelength band of sunlight according to each season. Based on this data, the quantitative relationship between the ultraviolet irradiation amount and the blood vitamin D And outputs a control signal for controlling the irradiation amount of the light source 140 according to the control signal.

The light source driving apparatus 130 outputs a light source driving signal for operating the light source 140 to the light source 140 in response to the control signal applied from the light source driving apparatus 130 or the mobile apparatus 120 .

The use of the vitamin D body synthesis induction system having such a structure is as follows.

When a user having the ultraviolet information sensing device 110 and the mobile device 120 uses the system of the present invention, the user inputs his / her physical characteristics and health state to the mobile device 120 first.

When the light source driving device 130 outputs a control signal for controlling the operation of the light source 140 for vitamin D synthesis, the mobile device 120 transmits the information input by the user to the light source driving device 130 Thereby making it possible to provide basic data for controlling the lighting state of the light source 140.

When the user moves, the ultraviolet information sensing device 110 continuously senses the intensity (intensity) of ultraviolet rays irradiated to the user.

The ultraviolet information sensing device 110 transmits information about the ultraviolet ray sensed by the ultraviolet information sensing device 110 to the mobile device 120 or the light source driving device 130. The mobile device 120 or the light source driving device 130 Calculates the degree of intensity of the light source 130 to be controlled in order to satisfy the amount of ultraviolet rays, and then controls the operation of the light source 130.

Meanwhile, the user may move outdoors and move to a place where the light source 140 is not installed. In this case, the ultraviolet information sensing device 110 transmits the amount of ultraviolet light detected by the mobile device 120, and the amount of ultraviolet light received from the outside (natural light other than artificial light through the light source 140) is continuously detected.

The mobile device 120 calculates the amount of ultraviolet rays necessary for the user by using the installed application. Therefore, when the user moves to the room again, the mobile device 120 may search for the amount of ultraviolet rays, Thereby allowing the light source 140 to adjust the dose.

In this specification, the description of control of the light source 140 for ultraviolet light may mean controlling the ratio of the ultraviolet light mixed in the visible light through the control of the UV generated light source, not the visible light.

In the present invention, all information sensed by the ultraviolet information sensing device 110 is transmitted to the mobile device 120 or the light source driving device 130 using the current Internet of Things (IoT) technology, And can be used for analyzing big data or extracting information about a user in the future by allowing all data to be transmitted to a database (DB) (not shown) to be stored.

The ultraviolet information sensing device 110 senses ultraviolet rays at predetermined intervals and can transmit the sensed ultraviolet rays to at least one of the mobile device 120 and the light source driving device 130.

At least one of the mobile device 120 and the light source driving device 130 calculates the amount of ultraviolet ray appropriate to the user by using the sun altitude, weather condition, age, working time, sleeping time, For this information, the system of the present invention may further include components such as a position data acquisition unit (e.g., GPS).

Since the wearable type ultraviolet information sensing apparatus 110 is exposed to the outside to be irradiated with sunlight, it can be configured in the form of a watch, a necklace, a waistband or the like worn on the user's wrist as described above.

The physical characteristics of the user input to the mobile device 120 may be at least one of the user's age, weight, sex, height, and the degree of his / her desired ultraviolet exposure set by the user.

However, the degree of UV exposure can be automatically adjusted to the appropriate level according to the age of the user. On the other hand, in the case of women, for cosmetics reasons, the appropriate exposure level can be set lower than required.

At least one of the mobile device 120 and the light source driving device 130 calculates the amount of ultraviolet rays that have been exposed to the user so far using the amount of ultraviolet rays sensed through the ultraviolet information sensing device 110, The amount of ultraviolet rays or the ultraviolet ray exposure time corresponding to the detected ultraviolet ray.

On the other hand, the system of the present invention may further include an output unit (e.g., an information display unit) that can inform the user of the amount of ultraviolet rays (the amount already absorbed and the amount required more in the future and the time when it is converted into time) .

Communication between the components through the communication network NT may be performed using at least one of WiFi, Long Term Evolution (LTE), 3G, Long Term Evolution-Advanced (LTE-A), Zigbee, And the information of the corresponding user can be automatically transmitted to a server (not shown) through an application installed in the mobile device 120. [

Next, referring to Fig. 2, an embodiment of the vitamin D body induction system of the present invention will be described.

First, referring to FIGS. 2 to 4, a system for inducing synthesis of a vitamin D body according to an embodiment of the present invention will be described.

2, the vitamin D body synthesis induction system of the present example comprises a vitamin D synthesis amount determination device 100 and an ultraviolet B illumination device 30 (a device for communicating with the vitamin D synthesis amount determination device 100 via a communication network NT) .

The vitamin D synthesis amount determination device 100 includes an ultraviolet information sensing device 10 and a vitamin D synthesis amount determination device 20 communicating with the ultraviolet information sensing device 10. [

The ultraviolet information sensing apparatus 10 senses the amount of ultraviolet ray B and the ultraviolet ray index UVI received during the exposure time exposed to ultraviolet rays and supplies data on the detected ultraviolet ray B and the ultraviolet ray index to the vitamin D synthetic amount determination device 20 ). The ultraviolet information detecting device 10 is a wearable device worn by a user or carried by a user, and is worn on a body part exposed to sunlight or carried by a user.

2, the ultraviolet information sensing apparatus 10 includes a driving switch 11 for ultraviolet information sensing operation, an ultraviolet ray B amount sensing unit 121 for sensing the amount of ultraviolet ray B (UV-B), an ultraviolet ray index An ultraviolet ray exponent detection unit 122 for detecting a UV index (UVI), a temperature detection unit 123 for outputting a temperature detection signal corresponding to a temperature sensed by sensing the temperature, A humidity sensing unit 124 for outputting a humidity sensing signal, a sensing switch 13 connected to the sensing switch 12-124, a storage unit 14 connected to the sensing control unit 13, And a communication unit 15 connected to the sensing control unit 13.

The drive switch 11 turns on or off according to the user's operation and outputs a signal corresponding to the on or off state to the sensing control unit 13. [

The ultraviolet ray B amount sensing unit 121 receives the sunlight and senses the amount of ultraviolet ray B that varies depending on the amount of received sunlight, and outputs a signal corresponding to the detected ultraviolet ray amount B to the sensing control unit 13.

The ultraviolet ray index sensing unit 122 senses the ultraviolet ray index of the sunlight exposed to the user and outputs a signal corresponding to the sensed ultraviolet ray index to the sensing control unit 13.

The temperature sensing unit 123 senses the ambient temperature as described above, and the humidity sensing unit 124 senses the ambient humidity.

The detection control unit 13 receives the signal from the drive switch 11 and determines the operation state of the drive switch 11. When the drive control unit 13 determines that the drive switch 11 is operated, And generates ultraviolet ray B amount sensing data and ultraviolet ray exponent detection data corresponding to the sensing signals applied from the ultraviolet ray B amount sensing unit 121 and the ultraviolet ray exponent sensing unit 122, And the data generated through the communication unit 15 after generating the temperature data and the humidity data respectively corresponding to the temperature and humidity sensed by using the temperature sensing signal and the humidity sensing signal applied from the sensing unit 124, To the device (20).

The storage unit 14 stores the ultraviolet ray B amount detection data, the ultraviolet ray exponent detection data, the temperature data, and the humidity data determined according to the detection signals output from the ultraviolet ray B amount sensing unit 121 and the ultraviolet ray exponent sensing unit 122 A storage medium, and a memory.

Further, the storage unit 14 stores data necessary for the operation of the ultraviolet information winding device 10.

The communication unit 15 is operated under the control of the sensing control unit 13 to perform communication between the ultraviolet information sensing apparatus 10 and the vitamin D synthesis amount determination apparatus 20 and communication between the ultraviolet information sensing apparatus 10 and the ultraviolet B illuminator 30, a mobile communication module, an internet module, and a short-range communication module.

At this time, the mobile communication module transmits and receives signals (i.e., radio signals) wirelessly with at least one of a base station, an external terminal, and a server on a mobile communication network.

The Internet module refers to a module for wireless or wired Internet access, and the Internet module can be built in or externally attached to the vitamin D judgment device 10.

WLAN (WiFi), Wibro (Wireless broadband), Wimax (World Interoperability for Microwave Access) or HSDPA (High Speed Downlink Packet Access) can be used as the Internet technology.

The short-range communication module is a module for short-range communication.

Bluetooth, radio frequency identification (RFID), infrared data association (IrDA), ultra wideband (UWB), or ZigBee may be used as the short range communication technology.

Next, the structure of the vitamin D synthesis amount determination device 20 will be described with reference to FIG.

The vitamin D synthesis amount determination device 20 may be a portable terminal such as a portable smart phone or a fixed terminal whose location is fixed.

4, the vitamin D synthesis amount determination device 20 is connected to a user input unit 21, an operation control unit 22 connected to the user input unit 21, an operation control unit 22, A communication unit 24 connected to the operation control unit 22 and an output unit 25 connected to the operation control unit 22.

The user input unit 21 generates a signal related to an input operation such as a command, data, or information for controlling the operation of the vitamin D synthesis amount determination device 20 by the user, and outputs the signal to the operation control unit 23.

The user input unit 21 may include a key pad, a dome switch, a touch pad, a jog switch, a mouse or a touch panel. have.

The position data acquisition unit 22 is a device for acquiring position data of the vitamin D synthesis amount determination device 20 through a Global Navigation Satellite System (GNSS).

In this case, the GNSS means a navigation system capable of calculating the position of a receiving terminal using a radio wave signal received from an artificial satellite (not shown). A specific example of the GNSS is a Global Positioning System (GPS) , Galileo, Global Orbiting Navigational Satellite System (GLONASS), COMPASS, Indian Regional Navigational Satellite System (IRNSS), and Quasi-Zenith Satellite System (QZSS).

The operation control unit 23 is a control module for controlling the operation of the vitamin D synthesis amount determination device 20. The control unit 23 controls the operation of the vitamin D synthesis amount determination device 20 based on the ultraviolet B amount sensing data transmitted from the ultraviolet information sensing device 10, And the ultraviolet ray exposure time to determine the present ultraviolet ray quantity B, the current ultraviolet ray index, the ultraviolet ray exposure time, the current temperature and the humidity.

Further, the operation control unit 23 calculates the amount of vitamin D synthesized in the body of the present user by ultraviolet rays using the determined amount of ultraviolet B and ultraviolet exposure time, and calculates the amount of vitamin D synthesized and the amount of vitamin D required per day And controls the operation of calculating the amount of vitamin D achieved and outputting it to the output unit 26.

At this time, the amount of vitamin D needed per day depends on the age and sex of the user.

In addition, the amount of vitamin achieved is calculated as the ratio of the amount of vitamin D synthesized to the amount of vitamin D required per day in the case of this example, which is the state of attainment of vitamin D, . When the attainment status of vitamin D is output as a value of vitamin D synthesis amount, there is no need to calculate the ratio (%) of the calculated amount of vitamin D to the required amount of vitamin D per day.

The operation control unit 23 also outputs the ultraviolet ray index and the current temperature and humidity to the output unit 26 to notify the user of the current ultraviolet ray index and temperature and humidity and determines the level to which the determined ultraviolet ray index belongs, And outputs a user recommendation message and an object according to the level and the level to the output unit 26.

The storage unit 24 is a storage medium that stores data and information necessary for operation of the operation control unit 23, and data or information generated during operation.

In addition, the storage unit 24 stores user information including the name of the user, the age and sex of the user, the skin type of the user, and the exposed area (%) of the user, whether or not the user information is interlocked with the ultraviolet B illuminator, The amount of vitamin D needed per day, the minimum erythemal dose (MED) per skin type, and the amount of vitamin D synthesis calculated.

The user's skin type has a value of one of 1 to 6, and the user selects and inputs a number corresponding to his / her skin type from the numbers 1 to 6 using the user input unit 21. [

The user's exposure area has a value selected by the user from 6% to 40%, and the user also uses the user's input unit 21 to calculate the exposure ratio of his or her entire skin area And selects a corresponding value. In the case of this example, the exposed area can be determined to be about 6% to 10% in spring, autumn and winter, and the exposed area can be set to about 20% to 40% in summer.

Whether the interaction with the ultraviolet B illuminating device is performed is determined by comparing the vitamin D synthesis amount determining device 20 and the ultraviolet B illuminating device 30 with each other to determine whether the operation of the ultraviolet illuminating device 30 Or not.

Therefore, when the ultraviolet ray B illuminating device 30 is in a state of being able to communicate with the vitamin D synthesizing amount determining device 20, the ultraviolet ray B illuminating device 30 transmits a notification signal indicating the interlocking state to the vitamin D synthetic amount determining device 20 ).

The vitamin D synthesis amount determination device 20 may store a value such as a state flag indicating whether the ultraviolet B illumination device 30 is interlocked with the storage device 24, State and save it.

At this time, whether or not the ultraviolet B illumination device 30 is interlocked with the ultraviolet B illumination device 30 can be determined by the Vitamin D synthesis amount determination device 20 and the ultraviolet B illumination device 30, The radio control state between the base stations 30 can be determined.

The communication unit 25 includes one or more modules that enable communication with the ultraviolet information sensing device 10 and communication with the ultraviolet B illuminating device 30 in the same manner as the communication unit 15 of the ultraviolet information sensing device 10 do.

The communication unit 25 includes a mobile communication module, an Internet module, and a local communication module.

Output 26 is for generating output related to visual, auditory, and tactile senses, and may include a display module, an audio output module, and a haptic module.

The display module displays the image corresponding to the image data or information output from the operation control unit 23 on the screen according to the operation of the operation control unit 23. [

Such a display module may be a liquid crystal display device or an organic light emitting display device.

At this time, the image output to the display module may be image data corresponding to the image data or information transmitted from the vitamin D judgment device 10. [

The sound output module outputs the audio signal output from the operation control unit 23 by the operation of the operation control unit 23 by voice.

The sound output module may include a speaker, a buzzer, and the like.

The haptic module generates various tactile effects that the user can feel. In this example, the haptic effect generated by the haptic module is vibration.

The intensity and pattern of the vibration generated by the haptic module can be changed by a control operation of the operation control unit 23. The haptic module may include a motor or the like operated under the control of the operation control unit 23 have.

The ultraviolet ray B illuminator 30 drives a light source driving device that controls the turning on and off of the ultraviolet B light source and the ultraviolet B light source.

At this time, the ultraviolet B light source can perform not only the irradiation function of ultraviolet ray B for vitamin D synthesis but also the function of providing illumination.

In this case, as shown in Fig. 14, by using the adjustment buttons (B11-B17) of the corresponding setting window outputted to the display module of the vitamin D synthesis amount determination device 20, the user presses the ultraviolet B illuminator 30 The color temperature, the illuminance, the red light source, the green light source, the lighting state of the blue light source, and the degree of the cool tone and the warm tone can be adjusted.

The light source driving device outputs the light source driving signal of the corresponding state, which controls the lighting state of the ultraviolet ray B light source, to the ultraviolet ray B light source according to the control signal transmitted from the vitamin D synthesis amount determining device 20, And the light-off state of the light-emitting element.

That is, when the control signal for starting driving is applied from the vitamin D synthesis amount determining device 20, the light source driving device controls the lighting operation of the ultraviolet B light source, And controls the extinction operation of the ultraviolet B light source when a signal is applied.

Next, the operation of the vitamin D body synthesis induction system of this embodiment having such a structure will be described with reference to FIGS. 5 to 7. FIG.

First, the operation of the ultraviolet information sensing device 10 will be described with reference to FIG.

When power is supplied to the ultraviolet information sensing apparatus 10 and operation is started, the sensing control unit 13 first reads a signal applied from the driving switch 11 to determine whether the driving switch 11 is operated by the user S11, S12).

If it is determined that the driving switch 11 of the ultraviolet information sensing apparatus 10 is operated (that is, turned on) by the operation of the user by the signal from the driving switch 11 (S12) 13 controls the operation of a power source unit and the like so that driving power can be supplied to the ultraviolet ray sensing unit 121, the ultraviolet ray exponent sensing unit 122, the temperature sensing unit 123, and the humidity sensing unit 124 , The ultraviolet information detecting operation of the ultraviolet information detecting device 10 is started (S13).

After the ultraviolet information sensing operation is started, the sensing control unit 13 operates a timer (not shown) to count the driving time of the ultraviolet ray B amount sensing unit 121 and calculates the ultraviolet ray exposure time as the counted ultraviolet exposure time, And stores it in the unit 14 (S14).

Then, the sensing controller 13 reads the sensing signal applied from the ultraviolet ray B sensing unit 121 and the ultraviolet ray exponent sensing unit 122 (S15), and detects the amount of ultraviolet B corresponding to the read sensing signal state Data relating to ultraviolet rays and ultraviolet ray index data, and stores the data in the storage unit 14 (S16).

The sensing control unit 13 reads the signals from the temperature sensing unit 123 and the humidity sensing unit 124 and generates temperature data and humidity data corresponding to the determined temperature and humidity and outputs the generated temperature data and humidity data to the storage unit 14 (S17, S18)

When the ultraviolet ray-related data and the environmental data including the temperature data and the humidity data are generated as described above, the detection control unit 13 detects ultraviolet-related data generated using the communication unit 15, The environmental data and ultraviolet exposure time are transmitted to the vitamin D synthesis amount determination device 20 (S19).

At this time, since the communication method between the ultraviolet information sensing device 10 and the vitamin D synthesis amount determination device 20 is already determined, the sensing control part 13 carries out the transmission operation of the corresponding data according to the determined communication method.

In this manner, the sensing controller 13 of the ultraviolet information sensing device 10 can measure the ultraviolet ray B amount sensing data, the ultraviolet ray exponent sensing data, the temperature data, the humidity data, and the ultraviolet ray exposure time by using the sensing portions 121-124 And transmitted to the vitamin D synthesis amount determination device 20.

In the case of this example, the ultraviolet information sensing apparatus 10 has the drive switch 11 and controls the operation state of the sensing units 121-124 according to the operation state of the drive switch 11, but alternatively, The drive switch 11 may be omitted.

When the drive switch 11 is omitted, the detection control unit 13 starts the ultraviolet information sensing operation by operating the sensing units 121-124 when a signal in a predetermined state is applied from the vitamin D synthesis amount determining apparatus 20 .

In addition, the order of generation of the ultraviolet ray B amount detection data, ultraviolet ray exponent detection data, temperature data, and humidity data can be changed as needed.

The components 11, 121-124, and 13-15 shown in FIG. 3 are not essential, and other components other than these components 11, 121-124, and 13-15 may be added or at least one of them And the components 21-26 shown in FIG. 4 are not essential either, so that other components may be added or at least one of the components may be omitted.

Next, the operation of the vitamin D synthesis amount determination device 20 will be described with reference to FIG. 6 and FIG.

First, when the operation of the vitamin D synthesis amount determination device 20 is started by supplying power necessary for the operation, the operation of the operation control part 23 is also started (S20).

Therefore, the operation control section 23 of the vitamin D synthesis amount determination device 20 uses the signal applied from the user input section 21 in the operation mode of the vitamin D synthesis amount determination device 20 to determine the vitamin D synthesis amount determination mode Is selected (S21).

When the vitamin D synthesis amount determination mode is selected by the user's operation (S21), the operation control unit 23 acquires the corresponding data, that is, ultraviolet B amount sensing data, ultraviolet ray exponent detection data, temperature data , Humidity data, and ultraviolet exposure time are transmitted (S22).

If the vitamin D synthesis amount determination mode is not selected by the user in step S21 (S22), the operation control section 23 reads the signal applied to the user input section 21 to determine whether the vitamin D synthesis amount determination mode is selected .

In this example, the operation of the vitamin D synthesis amount determination device 20 is controlled according to the operation mode selected using the user input unit 21. However, the present invention is not limited to this and the vitamin D synthesis amount determination device 20) can be controlled.

In this case, when the vitamin D synthesis amount determination device 20 is used to perform the vitamin D synthesis amount determination operation, the user can turn on the drive switch so that a signal in the ON state can be applied to the operation control part 23 . The operation control unit 23 starts the vitamin D synthesis amount determination operation when a signal of the ON state is applied from the drive switch, and proceeds to step S22 to determine whether data is transmitted from the ultraviolet information sensing apparatus 10.

When the ultraviolet ray-related data, the environmental data and the ultraviolet ray exposure time are transmitted from the ultraviolet information detecting apparatus 10 again to the step S22, the operation control unit 23 transmits ultraviolet ray-related data (that is, (I.e., humidity data and temperature data) and ultraviolet exposure time in the storage unit 24 (S23).

Next, the operation control unit 23 determines whether user information exists in the storage unit 24 (S24). If the user information is stored in the storage unit 24, the operation control unit 23 stores the user information in the storage unit 24 The user information is read (S25).

Then, the operation control unit 23 calculates the vitamin D synthesis amount using the inputted user information (S211).

However, when the user information necessary for calculating the amount of vitamin D synthesis in the storage unit 24 is not stored in the storage unit 24, the operation control unit 24 selects the user information from the data stored in the storage unit 24 And outputs the read image data to the display module of the output unit 26 (S26).

Therefore, the output unit 26 outputs the video corresponding to the video data applied from the operation control unit 23, and inputs the corresponding user information through the user information input window output by the user using the user input unit 21 Or to input user information by using a user information input window after confirmation of a character requesting input of user information.

In this example, an example of the user information input window is shown in FIG.

When all information related to user name, age, name, skin type, and exposed area, which is required user information, is input through the user input unit 21 (S27), the operation control unit 23 The user information is stored in the storage unit 24 (S28).

Then, the operation control unit 23 determines the amount of vitamin D required per day according to the sex and age of the user, using the data stored in the storage unit 14, stores the vitamin D required amount in the storage unit 24, 26) (S29, S210).

In the case of this example, the storage unit 24 already stores the daily amount of vitamin D required by sex and age.

After the user information is input from the user input unit 21 and output to the display module of the output unit 26, the operation control unit 23 proceeds to step S211 to calculate the amount of vitamin D synthesis .

However, if the user information is not input from the user input unit 21 (S27), the operation control unit 23 proceeds to step S21 and determines whether the operation mode selected by the user is the vitamin D plate determination mode.

When the operation state of the operation control section 23 goes to the vitamin D synthesis amount calculation step S211, the operation control section 23 judges the current ultraviolet ray amount B using the transmitted ultraviolet ray B amount sensing data.

Then, the operation control section 23 calculates the presently synthesized vitamin D synthesis amount using the ultraviolet ray B amount, the exposure area, and the ultraviolet ray exposure time currently determined according to the following formula (1).

Here, EUV is the erythema radiance, MED is the minimum erythema amount per skin type, Etime is the ultraviolet exposure time, and Eareas is the exposed area.

The erythema ultraviolet radiation (EUV) is determined by the following equation (2).

는 판정된 자외선 B량이다.Also,

Is the determined ultraviolet ray B amount.

The values of MED are determined for each user skin type as shown in the following Table 1, and the values of the minimum erythema quantity (MED) corresponding to each user skin type are stored in the storage unit 24.

user
Skin type Skin color MED [J / m ² ] Sun-reactive One White and very pale 200 Always buns, never tans 2 Pale white with beige tint 250 Always buns, easily tans minimally 3 Beige to light brown 300 Burns moderately tans uniformity 4 Light to moderate brown 450 Burns minimally always tans well 5 Medium to dark brown 600 Rarely burns tans profusely 6 Dark brown to black 1000 Never burns

In Table 1 above, the Korean skin type is generally '3' and the MED value corresponding to '3' is '300'.

Therefore, the operation control unit 23 determines a value (e.g., 6) corresponding to the user's skin type input by the user, and reads the MED value corresponding to the determined value from the storage unit 24. [

The ultraviolet ray exposure time Etime is an operation time of the ultraviolet ray B amount sensing unit 121 operated after the driving power is applied under the control of the sensing control unit 13 as described above, Is counted by a counting operation of a timer or the like and is transmitted from the ultraviolet information detecting apparatus 10. [

The exposure area Eareas is data input from the user through the user input unit 21. [

As already explained, the user can define the area of exposure on a seasonal basis, for example one of the values of about 6% to 10% in spring, autumn and winter can be defined as the area of exposure (Earea) , And in summer one value of about 20% to 40% can be defined as the exposed area (Earea).

As an example, Equation (1) for calculating the amount of synthesized vitamin D can be used to calculate the amount of synthesized vitamin D using the amount of ultraviolet ray B determined using the ultraviolet ray B amount sensing unit 121 It goes without saying that other equations can be used.

When the amount of vitamin D synthesized through the amount of ultraviolet B exposed during the current ultraviolet exposure time is calculated using the equations already stored in the storage unit 24, the operation control unit 23 determines the age and sex of the user (%) Indicating the amount of vitamin D synthesis that has been synthesized at present, to a certain level of daily vitamin D requirement, using the amount of vitamin D required per day and the calculated amount of vitamin D synthesis Amount / amount of vitamin required per day) × 100] and stores it in the storage unit 24 (S212).

Then, the operation control section 23 determines whether the synthesized amount of synthesized vitamin D has reached the daily vitamin D requirement (S213).

However, if the synthesized vitamin D synthesis amount does not reach the required daily vitamin D level (S213), the operation control unit 23 determines whether the current user exists in the room (S214).

At this time, whether or not the user is indoors is determined by the user's operation using the user input unit 20, and a state value corresponding to whether the user is indoors may be stored in the storage unit 24. [

In this case, the operation control unit 23 can read the status value stored in the storage unit 24 and determine whether the user is present in the room where the ultraviolet B illuminating device 30 is installed.

As another example, indoor equipment for performing wireless communication (e.g., Wi-Fi communication) with a mobile device (e.g., an ultraviolet information device 10 or a vitamin D composite amount determination device 20) It is possible to determine whether or not the user is indoors. For example, when indoor equipment is determined to be in a user's indoor position using RSSI (Received Signal Strength Indication) value or the like via wireless communication between mobile devices, the indoor equipment is operated by the operation control unit (23) to inform that the user is located indoors. At this time, the information of the vitamin D synthesis amount determining device 20 and indoor equipment communicating with each other is already stored in the storage portion of the vitamin D synthesis amount determination device 20 and the indoor equipment.

If it is determined that the user is currently located in the room (S212), the operation control section 23 uses the data stored in the storage section 24 to determine whether or not the user is interlocked with the ultraviolet B illuminating device 30 (S215 ).

When the vitamin D synthesis amount determining device 20 is judged to be in a state of interlocking with the ultraviolet B illuminating device 30 in step S215, the operation controlling part 23 controls the ultraviolet B illuminating device 30, And outputs a control signal for turning on the B (S216).

At this time, the operation control unit 23 calculates the lighting time of the corresponding ultraviolet B light source in consideration of the intensity of the ultraviolet B light source, the presently synthesized vitamin D synthesis amount, and the difference in the required amount of vitamin D, It is possible to output a control signal for turning on the light source.

Therefore, the light source driving apparatus of the ultraviolet ray B illuminating device 30 turns on the ultraviolet ray B light source so that the ultraviolet ray B illuminates so that the vitamin D synthesis can be performed in the room.

In an alternative example, the operation control unit 23 may output a control signal to the ultraviolet B illuminator 30 that is interlocked when the amount of vitamin D synthesis does not reach the required amount of vitamin D, regardless of whether the user is present or absent . In this case, the operation of step S214 is omitted.

Then, the operation control unit 23 determines the current ultraviolet ray index using the transmitted ultraviolet ray exponent data stored in the storage unit 24 (S217).

If the vitamin D synthesis amount reaches the required amount of vitamin D in step S211 and the vitamin D achievement amount is 100% or more, the user is outdoors in step S212 (S217), and in step S213, If it is not in a state of interlocking with the B illuminating device (S213), the process goes to step S217 to determine the current ultraviolet ray index.

Next, the operation control section 23 uses the determined ultraviolet ray index to determine which level among the plurality of levels the currently determined ultraviolet ray index belongs to (S218). In this example, the level of the ultraviolet ray index is divided into, but not limited to, 'low', 'normal', 'high', 'very high' and 'dangerous'.

Since the ultraviolet ray exponent range has already been determined for each level in the storage section 24, the operation control section 23 determines the level to which the determined ultraviolet ray index belongs and determines the level of the currently determined ultraviolet ray index.

When the level of the current ultraviolet ray index is determined (S218), the operation control section 23 reads the position data from the position data obtaining section 22 and determines the present position of the vitamin D synthetic amount determination device 20 And stores it in the storage unit 24 (S219, S220).

The operation control unit 23 receives a user recommendation message and a user recommendation message for the determination result, that is, the determined current temperature, the current humidity, the current ultraviolet ray index, the present vitamin D achievement amount, the current position information, the ultraviolet ray index level, From the storage unit 24 and outputs the read image data to the display module of the output unit 26 (S221).

Therefore, the display module of the output unit 26 outputs an image corresponding to the output image data, and as a result, the display module of the output unit 26 of the vitamin D synthesis amount determination device 20 displays, A user recommendation message corresponding to the current position, the current temperature and humidity, the present vitamin D achievement amount, the current ultraviolet ray index, the current ultraviolet ray index, the ultraviolet ray index level and the level, as shown in one example in FIG.

In the case of this example, the user recommendation message according to the level of ultraviolet ray index is as follows. If the ultraviolet level is low, it is preferable to go for a walk. If the ultraviolet level is low, a hat, sunglasses and sunscreen must be packed. 'If it is' High', 'It is better to wear long sleeves',' Very high ',' Stay in the shade, please apply sunscreen ' And these user recommendation messages are already stored in the storage unit 14. [

Also, the shape of the object OB output for each step of the determined ultraviolet ray indexes may be changed according to the user recommendation message, as shown in FIGS. 9 to 13.

Thus, through the image output through the display module of the output unit 26, the user can recognize the current vitamin D achievement amount, the exact position (i.e., address) where the user is located, and the ultraviolet ray index, Is known accurately and easily.

The output information of the output unit 26 can be used by the user to determine whether the user is outdoors or the like so that the user can reduce the risk of skin cancer due to excessive exposure to ultraviolet rays or the problems of metabolism due to insufficient exposure to ultraviolet rays do.

As described above, in the vitamin D system induction system of the present example, the amount of vitamin D produced by the user in terms of the amount of ultraviolet B is determined using the amount of ultraviolet B, and the amount of vitamin D synthesized and the user's daily vitamin D requirement And if the vitamin D synthesis amount does not satisfy the vitamin D requirement per day, the interlocked ultraviolet B illuminator 30 is automatically turned on or the ultraviolet B illuminator The ultraviolet ray B can be irradiated to a user who has a low amount of vitamin D synthesized.

Furthermore, when the vitamin D synthesis amount determining device 20 is not interlocked with the ultraviolet B illuminating device 30 and a state in which the vitamin D achieving amount is insufficient is output through the output part 26, B device 30 is operated so that the light of the ultraviolet ray B can be irradiated so that the insufficient amount of vitamin D can be replenished in the room.

As already described, the amount of vitamin D achieved (%), which is the ratio of the calculated amount of vitamin D to the amount of vitamin D required per day as a state of achieving vitamin D, is output to the output unit 26. Alternatively, D synthesis amount, as well as the vitamin D achievement amount, or only the vitamin D synthesis amount, may be output. When only the amount of synthesized vitamin D is output as the state of achieving vitamin D, the step of calculating and storing the amount of achieved vitamin D (S212) is omitted.

As shown in FIG. 15, according to the menu selection operation displayed on the output unit 16 by the user, the operation control unit 23 displays the ultraviolet ray index and the vitamin D composite amount determined during the period selected by the display module in a graph form Can be output. Thus, the user can graphically confirm the ultraviolet ray index and the rate of change of the vitamin D synthesis amount.

In this example, the ultraviolet information sensing device 10 includes a separate ultraviolet ray B amount sensing part 121 for sensing the amount of ultraviolet ray B, but in an alternative example, the ultraviolet ray amount sensing part 121 may be omitted .

In this case, the operation control section 23 of the vitamin D synthesis amount determination device 20 can calculate the ultraviolet ray amount B using the ultraviolet ray index determined using the ultraviolet ray index sensing data transmitted from the ultraviolet information sensing device 10 have. That is, the amount of vitamin D synthesis can be calculated by calculating the value of 83% of the determined ultraviolet ray index as the amount of ultraviolet ray B. In this case, since the ultraviolet ray B amount sensing unit 121 is omitted, manufacturing cost is reduced.

If the ultraviolet ray B amount sensing unit 121 is omitted, the sensing control unit 13 counts the ultraviolet ray exposure time using the operating point of the ultraviolet ray exponent sensing unit 122.

Also, in this example, the user can set the alarm function by setting the alarm temperature, the alarm humidity, the alarm ultraviolet ray index, and the informed vitamin D achievement amount through the corresponding alarm setting window using the user input unit 21. [ When at least one of the determined temperature, humidity, ultraviolet ray index, and vitamin D achievement reaches the alarm temperature, alarm humidity, alarm ultraviolet ray index, and notified vitamin D achievement amount, the operation control unit sets the haptic module or sound Output module to inform the user that at least one of the current temperature, humidity, UV index, and vitamin D achievement has reached a predetermined value.

Next, with reference to FIG. 16 and FIG. 17, a system for inducing synthesis of a vitamin D body according to another embodiment of the present invention will be described.

In FIGS. 16 and 17, as compared with FIG. 2 to FIG. 4, constituent elements having the same structure and performing the same function are given the same reference numerals as those of FIG. 2 to FIG. 4, It is omitted.

In the vitamin D synthesis induction system shown in FIG. 16, the vitamin D synthesis amount determining apparatus 100a includes an ultraviolet B amount sensing unit 121, an ultraviolet ray exponent sensing unit 122, a temperature sensing unit 123, 124, and is identical to the system shown in FIG. 2 except that the ultraviolet information sensing apparatus 10 is omitted. Therefore, in this example, the vitamin D synthesis amount determination device 100a becomes the vitamin D synthesis amount determination device.

17, the vitamin D synthesis amount determining apparatus 100a includes an ultraviolet B amount sensing unit 121, an ultraviolet ray exponent sensing unit 122, a temperature sensing unit 123, a humidity sensing unit 124, An operation control unit 23a connected to the user input unit 21, the position data obtaining unit 22, the sensing unit 121-124, the user input unit 21 and the position data obtaining unit 22, A connected storage unit 24, a storage unit 25 connected to the operation control unit 23a, and an output unit 26 connected to the operation control unit 23a.

Also in this example, the ultraviolet ray B amount sensing unit 121 may be omitted.

The operation of the vitamin D synthesis amount determination system of this example having such a structure is similar to the operation shown in Figs. 6 and 7 as shown in Figs. 18 and 19.

6 and step S23 are omitted and the operation control section 23a determines whether or not the vitamin D synthesis amount determination apparatus 100a is in the required state (step S22) Except that the detection signals applied from the sensors 121-124 are directly read in S39, S310, S316, S320, and S321 to determine the current amount of ultraviolet B, ultraviolet index, temperature, The operations of steps S30-S322 shown in Figs. 18 and 19 are substantially the same as those described with reference to the drawings shown in Fig. 6 and Fig. Therefore, the operation of the vitamin D synthesis amount determination system is omitted.

When at least one of the ultraviolet ray B amount sensing unit 121 and the ultraviolet ray exponent sensing unit 122 is operated by the system of the present embodiment, the operation control unit 23 controls the ultraviolet ray amount sensing unit 121 The time is counted from the time when at least one of the ultraviolet ray exponent detecting units 122 is operated and is stored in the storage unit 24 as the ultraviolet ray exposure time.

When the ultraviolet ray B amount sensing unit 121 is omitted, the operation control unit 23 determines the current ultraviolet ray index using the signal from the ultraviolet ray exponent sensing unit 122 in step S39, The amount of ultraviolet B is determined using the determined ultraviolet ray index, and the amount of vitamin D synthesized is calculated (S310). In this case, since the ultraviolet ray index has already been determined in step S39, the operation in step S316 is omitted.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

100, 100a: Vitamin D synthesis amount determination device 10: Ultraviolet information sensing device
20: Vitamin D synthesis amount determination device 30: Ultraviolet B illumination device
121: ultraviolet ray B amount sensing unit 122: ultraviolet ray exponent sensing unit
23: Operation control unit 24:
26: Output section

Claims (20)

The amount of vitamin D synthesized by the user relative to the amount of ultraviolet B amount to be determined is calculated using the amount of ultraviolet B amount determined, and the obtained state of vitamin D is determined by comparing the amount of synthesized vitamin D with the amount of daily vitamin D needed by the user A vitamin D synthesis amount determination device that allows the user to be irradiated with ultraviolet light B if the amount of synthesized vitamin D does not satisfy the required daily vitamin D amount,
An ultraviolet B light source, and an ultraviolet B light source for illuminating the ultraviolet light B to illuminate the ultraviolet light B by the user, Device,
The vitamin D synthesis amount determination device comprises:
An ultraviolet B amount sensing unit and at least one ultraviolet ray exponent sensing unit, and transmits ultraviolet ray B amount sensing data and ultraviolet ray exponent sensing data output from at least one of the ultraviolet ray B amount sensing unit and the ultraviolet ray exponent sensing unit to an operation control unit Ultraviolet information sensing device, and
A vitamin D synthesis amount is calculated using the ultraviolet ray B amount determined by using the ultraviolet ray B amount sensing data or the ultraviolet ray exponent detection data, the minimum erythema amount per skin type, the ultraviolet ray exposure time, and the ultraviolet ray exposure area, When the vitamin D synthesis amount is compared with the vitamin D synthesis amount and the daily vitamin D requirement level, or when the calculated vitamin D synthesis amount does not reach the daily vitamin consumption amount, a control signal for lighting the ultraviolet B light source is output to the ultraviolet B illuminator And
/ RTI >
In the case of the ultraviolet ray exposure area, one of the values of 6% to 10% in winter can be defined as the exposed area, and in summer, one of 20% to 40%
Vitamin D body synthesis induction system. The method of claim 1,
The ultraviolet B plate quantification amount, the minimum erythema amount of the user's skin type, the ultraviolet ray exposure time of the user, and the ultraviolet ray exposure area of the user. The method of claim 1,
Wherein the user's daily vitamin D requirement is determined according to the age and sex of the user. delete delete delete delete The method of claim 1,
Further comprising an output unit connected to the operation control unit and outputting a vitamin D attained state output from the operation control unit. The method of claim 1,
The operation control unit determines ultraviolet ray index using externally applied ultraviolet ray exponent detection data, and the amount of vitamin D synthesis is calculated according to the following equation
Vitamin D body synthesis induction system.
[Mathematical Expression]

(Where EUV is the erythema of ultraviolet radiation, MED is the minimum erythema amount per skin type, Etime is ultraviolet exposure time, and Eareas is the exposed area.
Also, 1MED is equivalent to 40IU when exposed to 1% of body area. delete 9. The method of claim 8,
Wherein the operation control unit determines a level to which the determined ultraviolet ray index belongs, and outputs a user recommendation message corresponding to the determined level and the determined level to the output unit. 10. The method according to claim 1 or 9,
Wherein the operation control unit calculates the ultraviolet B plate specific amount using the determined value of the ultraviolet ray index. 3. The method of claim 2,
Wherein the operation control unit determines the age and sex of the user stored in the storage unit and reads the vitamin D required amount corresponding to the determined age and gender from the storage unit. delete delete Calculating the amount of vitamin D synthesis using the amount of ultraviolet B amount determined,
Reading the required amount of vitamin D per day corresponding to the age and gender of the user in the storage section, calculating the amount of vitamin D synthesis using the amount of ultraviolet B value determined,
Reading the daily vitamin D requirement corresponding to the user's age and gender in the storage unit, and
Comparing the vitamin D synthesis amount with the daily vitamin D requirement level and outputting the vitamin D achievement status to the output unit
Determining whether the calculated amount of vitamin D synthesis has reached the required daily vitamin amount, and
And outputting a control signal for turning on the ultraviolet B light source to the ultraviolet B illuminator when the calculated amount of the vitamin D synthesized does not reach the required daily vitamin amount
Lt; / RTI >
The step of calculating the amount of vitamin D synthesis using the amount of the ultraviolet B-
The minimum erythema amount of the user's skin type, the ultraviolet ray exposure time of the user, and the ultraviolet ray exposure area of the user are further stored in the storage unit,
The amount of vitamin D synthesis is calculated using the amount of the ultraviolet ray B amount, the minimum erythema amount of the user's skin type, the ultraviolet ray exposure time of the user, and the ultraviolet ray exposure area of the user,
In the case of the ultraviolet ray exposure area, one of the values of 6% to 10% in winter can be defined as the exposed area, and in summer, one of 20% to 40%
A method for controlling a vitamin D synthesis amount determination apparatus. 17. The method of claim 16,
Determining ultraviolet ray index using ultraviolet ray exponent data corresponding to the ultraviolet ray exponent detection signal or ultraviolet ray exponent detection signal, and
And outputting the determined ultraviolet ray index to the output unit
Wherein the vitamin D synthesis amount determination device further comprises: The method of claim 17,
Determining a level to which the determined ultraviolet ray index belongs among a plurality of levels stored in the storage section,
Reading a user recommendation message corresponding to the determined level from the storage unit, and
And outputting the level of the ultraviolet ray index and the user recommendation message to the output unit
Wherein the vitamin D synthesis amount determination device further comprises: The method of claim 17,
Wherein the ultraviolet B plate quantification is calculated using the determined ultraviolet ray index value, and the vitamin D synthesis amount is calculated according to the following equation.
[Mathematical Expression]

(Where EUV is the erythema of ultraviolet radiation, MED is the minimum erythema amount per skin type, Etime is ultraviolet exposure time, and Eareas is the exposed area.
Also, 1 MED is equivalent to 40 IU when exposed to 1% of body area.) delete

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