KR101910488B1 - Vitamin D synthetic health lighting system - Google Patents

Abstract

The present invention relates to a vitamin D synthetic health lighting system. The vitamin D synthetic health lighting system includes an illumination module which includes an illumination part which includes an illumination LED for emitting light to a space and an ultraviolet LED for emitting an ultraviolet ray, a control part for controlling the illumination LED and the ultraviolet LED, and a first communication part; and a private module which includes a data part for storing user information, a detection part for detecting an ultraviolet ray index, an analysis part for deriving the ultraviolet ray accumulation of a user based on the ultraviolet ray index detected by the detection part and analyzing the derived ultraviolet ray accumulation and the user information of the data part and deriving ultraviolet LED control information, and a second communication part for transmitting ultraviolet LED control information derived from the analysis part to the first communication part. The total amount of ultraviolet irradiation in outdoor and indoor spaces of the user can be monitored.

Description

Vitamin D synthetic health lighting system {

The present invention relates to an illumination system capable of inducing optimal vitamin D synthesis in the body through an appropriate amount of ultraviolet irradiation in a room.

In general, a lighting lamp is used for illuminating a dark space in an indoor or outdoor environment. Fluorescent lamps are mercury and argon in a vacuum glass tube coated with a fluorescent material and convert ultraviolet rays generated by the discharge of mercury into visible light.

However, compared to incandescent lamps, fluorescent lamps have a small power consumption but a short life span, resulting in a short replacement cycle. Further, a ballast for applying a high voltage for the initial discharge of the fluorescent lamp is applied. LEDs (light emitting diodes) that emphasize long lifetime, light emission at low power, and compact size and eco-friendliness due to manufacturing are becoming major lighting lamps in comparison with the power consumption and lifetime of such fluorescent lamps. However, LED lighting has a disadvantage of high manufacturing cost, but it can be installed at low cost in the case of mass production due to expansion of the application range. In particular, since it boasts a life of 100,000 hours, the initial installation cost is somewhat high. It is expected that the use cost will be reduced over time.

On the other hand, vitamin D, commonly called calciferol, is one of the fat soluble vitamins and is known to be contained in liver oil, tuna, sardines, milk, and egg yolk. This vitamin D can be converted to vitamin D in the subcutaneous layer by the ultraviolet rays contained in the sunlight if the sunlight is sunlighted outdoors for a certain period of time even if the vitamin D is not consumed separately. It does not cause rickets or osteoarthritis.

However, in a busy modern society, there is a lot of time spent indoors, which is not directly exposed to sunlight, and there is too little time for outdoor activities that can be directly exposed to sunlight. Especially for growing children, The time spent in front of a TV, a computer, or a video game machine is increasing. In addition, ultraviolet rays contained in the sunlight are blocked by fine dust or contaminated air in the atmosphere, and the amount of the ultraviolet rays reaching the ground is significantly reduced.

For example, Korean Patent Registration No. 10-1562208 discloses a technique for compensating for the lack of vitamin D that can result from a shortage of outdoor activities such as a lighting environment adapted to natural light characteristics in an indoor space or an underground space. And emits ultraviolet rays that induce in vivo synthesis of vitamin D. The amount of ultraviolet rays emitted is varied according to the state information of a user using the indoor space or the underground space, To provide an in-vivo synthesis induction system for vitamin D.

Korean Patent Registration No. 10-1562208

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a method of monitoring the total amount of ultraviolet rays irradiated in a room, And to provide an illumination system that allows the illumination system to be realized.

As a means for solving the above problems, the vitamin D synthetic health lighting system (hereinafter referred to as "the system of the present invention") of the present invention comprises an illumination LED for illuminating an illumination in the space and an ultraviolet LED A lighting module, a control unit for controlling the illumination LED and the ultraviolet LED, and a first communication unit; An ultraviolet ray index calculation unit for calculating ultraviolet ray accumulation amount of the user on the basis of the ultraviolet ray index detected by the detection unit and analyzing the derived ultraviolet ray accumulation amount and user information of the data unit, And an individual module including an analysis unit for deriving information and a second communication unit for transmitting ultraviolet LED control information derived from the analysis unit to the first communication unit.

As an example, the analysis unit compares the ultraviolet accumulation amount of the user with the critical ultraviolet accumulation amount of the user stored in the data unit and derives a warning signal when the ultraviolet accumulation amount of the user exceeds the critical ultraviolet accumulation amount. Is characterized in that the ultraviolet LED is turned off.

For example, the personal module may be configured in a wearable device, and the wearable device may include a display unit on which the warning signal can be displayed.

As an example, a third communication unit configured to receive ultraviolet LED control information derived from the analyzing unit through a second communication unit is configured by a second ultraviolet LED mounted on a wall surface of the space and irradiating ultraviolet rays, And a second control unit for controlling the second ultraviolet LED according to a received signal.

As an example, when a plurality of users exist in the space, a warning signal is generated in a personal module of some users, and the second ultraviolet LED is turned on when the ultraviolet LED of the lighting module is turned off.

As one example, the individual irradiation module may include an irradiation unit having a second ultraviolet LED and irradiating ultraviolet rays, a rotating plate formed on the lower surface of the irradiation port to allow rotation of the irradiation port, and a support base hinged to the rotation plate And a body having a connector, a second communication unit, and a second control unit, and a reflector plate having a concave shape formed on an upper surface thereof and connected to the support unit.

As described above, the system of the present invention has an advantage of inducing the in-vivo synthesis of vitamin D by providing an illumination environment similar to natural light in the room.

In addition, the system of the present invention has an advantage of controlling the exposure of the ultraviolet rays to the individual by monitoring the environment exposed to the ultraviolet rays outdoors and indoors.

1 is a block diagram illustrating the present invention,
2 is a use state diagram of the present invention,
3 is a schematic view showing another embodiment of the present invention,
Figure 4 is a schematic diagram showing an embodiment of the individual survey module shown in Figure 3,
5A and 5B are operational state diagrams of the individual irradiation modules shown in FIG.

Hereinafter, the structure and operation of the present invention will be described in more detail with reference to the accompanying drawings. In describing the present invention, terms and words used in the present specification and claims are to be construed in accordance with the principles of the present invention, on the basis that the inventor can properly define the concept of a term in order to best explain his invention It should be construed as meaning and concept consistent with the technical idea of.

1, the system 1 of the present invention includes an illumination unit 21 having an illumination LED 211 for illuminating an illumination in a corresponding space and an ultraviolet LED 212 for irradiating ultraviolet rays, And a control unit (22) for controlling the ultraviolet LED (212); a lighting module (2) including a first communication unit (23); A detection unit 32 for detecting an ultraviolet ray index, a data unit 31 for storing user information, a detection unit 32 for deriving ultraviolet ray accumulation amount of the user based on the ultraviolet ray index detected by the detection unit 32, An analysis unit 33 for analyzing user information of the ultraviolet LED control unit 31 to derive ultraviolet LED control information and an ultraviolet LED control information generation unit 33 for acquiring ultraviolet LED control information from the second communication unit 23, And a personal module (3) including a communication unit (34).

That is, the present invention includes a personal module 3 interlocked with the lighting module 2 formed in the corresponding space (room a), in the room a, as well as in the outdoor b and the room a As shown in FIG. 2, the personal module 3 is worn by each user in the form of a wearable device. The user wearing the personal module 3 can be installed in the outdoor (b) and indoor a) to be exposed to an appropriate ultraviolet ray so that an appropriate vitamin D is synthesized in the body. Here, exposure to an appropriate ultraviolet ray allows the user to make a shortage of exposure dose of ultraviolet rays for the synthesis of vitamin D in outdoor (b) by illumination in the room (a), and in addition to the excess portion of the total ultraviolet ray dose Monitoring and control.

The illumination module 2 includes an illumination unit 21 having an illumination LED 211 for illuminating an illumination in a corresponding space and an ultraviolet LED 212 for irradiating ultraviolet rays and an illumination unit 21 for illuminating the illumination LED 211 and the ultraviolet LED 212 , And a first communication unit (23).

In the illumination unit 21, the illumination LED 211 is configured for general illumination, and it is preferable that the light wavelength, the color temperature, and the like according to time and season are adjusted. In this way, the color temperature and the like can be controlled by the control unit 22 according to the user, and the control unit 22 controls the operation mechanism based on the user data stored in the data unit 31 You can.

The ultraviolet LED 212 corresponds to a configuration for irradiating ultraviolet rays having a wavelength of 280 nm to 320 nm in order to induce synthesis of vitamin D in the body during lighting.

Ultraviolet rays having a wavelength in the above range (UV-B) function to produce vitamin D in the body as mentioned above. Vitamin D is generated by exposing the body surface to sunlight. At this time, the effect of ultraviolet rays converted into vitamin D depends on various factors such as ultraviolet light intensity, hair, smoke, fog, and dust which are exposed to the skin. Excessive intake of vitamin D causes side effects such as increase in blood calcium concentration and kidney damage cause.

For this, proper exposure to ultraviolet rays is required. The appropriate ultraviolet exposure is not determined uniformly but depends on various factors such as the user's age, body shape and current disease. For example, from birth to 1900 years old, 1000 IU per day, And the need for 1,500 IU to 2,000 IU for three adults and pregnant women.

That is, the optimal ultraviolet exposure dose for the proper vitamin D intake is different for each user. In the present invention, the personal module 3 is provided so as to control the optimal ultraviolet dose amount in a customized manner. The ultraviolet LED 212 is controlled by allowing the personal module 3 to transmit an appropriate signal to the control unit 22 of the lighting module 2 through the first communication unit 23.

The personal module 3 includes a data section 31 for storing user information, a detection section 32 for detecting an ultraviolet ray index, and an ultraviolet ray detection section 32 for detecting a ultraviolet ray accumulation amount of the user based on the ultraviolet ray index detected by the detection section 32 An analysis unit 33 for deriving ultraviolet LED control information by analyzing ultraviolet ray accumulation amount and user information of the data unit 31 derived and deriving the ultraviolet LED control information, And a second communication unit 34 that transmits the data to the communication unit 23.

The data part 31 stores various information of the user of the personal module 3 and stores the age and physical characteristics of the user as factors for deriving an appropriate amount of ultraviolet light exposure as described above, Quot ;, and "

The detection unit 32 for detecting the ultraviolet ray index corresponds to a configuration for measuring the ultraviolet ray index which is currently exposed to the user. The technology for measuring the ultraviolet ray index is a well-known technology, and thus a detailed description thereof will be omitted. 2, the detecting unit 32 measures the ultraviolet ray exponent exposed by the sunlight in the outdoor (b) and the ultraviolet ray exposures exposed by the ultraviolet LED 212 in the room (a), as shown in FIG.

The analyzing unit 33 derives the ultraviolet accumulation amount of the user based on the ultraviolet ray index detected by the detecting unit 32. Here, the term 'ultraviolet accumulation amount' refers to a concept that includes the ultraviolet accumulation amount by the ultraviolet LED 212 in the room (a) as well as the ultraviolet accumulation amount by sunlight in the outdoor (b) by the user in a real-

The analysis unit 33 derives the ultraviolet ray accumulation amount of the real time user and analyzes the derived ultraviolet ray accumulation amount and the user information of the data unit 31 to derive ultraviolet LED control information.

That is, the analyzing unit 33 compares the ultraviolet accumulation amount of the user with the critical ultraviolet accumulation amount of the user stored in the data unit 31 and derives a warning signal when the ultraviolet accumulation amount of the user exceeds the critical ultraviolet accumulation amount, The warning signal transmitted to the first communication unit 23 is transmitted to the controller 22 through the second communication unit 34 and the control unit 22 transmits the warning signal to the first communication unit 23, (212) is turned off. Here, the critical ultraviolet accumulation amount is a customized optimum ultraviolet accumulation amount preset by the age, physical characteristics, etc. of the user stored in the diving unit 31.

This arrangement allows the user to be exposed to ultraviolet rays by the ultraviolet LED 212 in the room (a) when sufficient ultraviolet ray exposure is not performed in the outdoor space (b), and the ultraviolet ray exposure by the outdoor (b) The total ultraviolet accumulation amount due to the ultraviolet ray exposure by the ultraviolet LED 212 in the room (a) is automatically monitored. When the ultraviolet ray accumulation amount is exceeded, the ultraviolet LED 212 is automatically turned off so that the side effect .

The personal module 3 can be configured in a wearable device as shown in FIG. 2 and the like, and can be executed in the form of an app on a personal terminal although it is not shown in the drawing. In this case, the personal module 3 may include a display unit 35 on which the warning signal can be displayed. In particular, according to the configuration of the display unit 35, So that an appropriate UV cutoff measure is achieved as the signal is displayed.

In addition, the system 1 of the present invention provides an example in which the individual survey module 4 is further configured as shown in FIG.

Although the individual irradiation module 4 is not shown in the drawing, when a plurality of users are present in the room (a), the ultraviolet ray exposure of the remaining user is supplemented when the ultraviolet LED 212 is turned off .

The individual irradiation module 4 includes a second ultraviolet LED 41 mounted on a wall surface of the space and irradiating ultraviolet rays, and the ultraviolet LED control information derived from the analysis unit 33 is transmitted to the second communication unit 34 And a second control unit 42 for controlling the second ultraviolet LED 41 in accordance with a signal received by the third communication unit 43. The second control unit 42 includes a third communication unit 43 that receives the second ultraviolet LED 41 through the second communication unit 43,

When a plurality of users are present in the space, a warning signal is generated in the personal module 3 of some users and the ultraviolet LED 212 of the lighting module 2 is turned off by the above-mentioned operating mechanism, Is received by the third communication unit 43 through the second communication unit 34 and the warning signal is transmitted to the second control unit 42 so that the second ultraviolet LED 41 is turned on in the second control unit 42 So that the remaining user is irradiated with the ultraviolet rays by the second ultraviolet LED 41.

Preferably, the individual irradiation module 4 is formed on only one side wall of the space, and the second ultraviolet LED 41 reduces the number of LED diodes so that ultraviolet rays are irradiated only in a part of the space, The individual irradiation module 4 moves to a portion irradiated with ultraviolet rays to supplement the ultraviolet ray irradiation amount.

More preferably, although not shown in the drawing, the space in which the individual irradiation module 4 is installed and the remaining space in the space can be partitioned by any means.

That is, the ultraviolet LED 212 of the lighting module 2 is irradiated all over the space so that ultraviolet rays are irradiated to all the users in the corresponding space. The individual irradiation module 4 irradiates the individual irradiation modules 4 The second ultraviolet LED 41 is irradiated with ultraviolet rays.

In addition, in the present invention, in the construction of the individual survey module 4, the survey range is adjusted so that the efficiency of selectively irradiating only a desired user is further increased.

The individual irradiation module 4 of the present embodiment includes an irradiation port 45 for irradiating ultraviolet rays with a second ultraviolet LED 41 incorporated therein and an irradiation port 45 formed on the lower surface of the irradiation port 45, The second communication unit 43 and the second control unit 42 constitute a connection port 46 including a rotation plate 461 for allowing the rotation plate 461 to rotate and a support base 462 hinged to the rotation plate 461, And a body 44 having a side surface attached to a wall surface of the space and a reflective plate 441 having a recessed shape formed on the other side thereof and connected to the support base 462.

The irradiation port 45 corresponds to a configuration in which ultraviolet light is irradiated by the second ultraviolet LED 41 on one side.

The connection port 46 corresponds to a configuration in which the irradiation port 45 is rotatable in all directions as shown in FIG. 4 while fixing the irradiation port 45 to the body 44. The connection port 46 is formed by a rotary plate 461 formed on the lower surface of the irradiation port 45 and allowing the irradiation port 45 to rotate and a support 462 hinged to the rotary plate 461 do.

The rotation plate 461 is attached to the lower surface of the irradiation port 45 and is rotatably interlocked S1 in the horizontal direction at the support stand 462. The rotation plate 461 is rotatably supported at the support stand 462, Can be implemented by various known structures, and thus the detailed description thereof will be omitted.

One end of the support base 462 is attached to the upper surface of the body 44 and the other end of the support base 462 is hinged to the rotation plate 461 to enable the hinge interlocking S2 in the longitudinal direction.

The body 44 has various electrical components such as the second communication unit 43 and the second control unit 42 mounted therein and has one side attached to a wall surface of the corresponding space and a reflective plate 441 ) Are formed on the substrate.

5A, when the ultraviolet rays are irradiated to only a narrow portion of the individual irradiation module 4, the individual irradiation module 4 is rotated in the desired direction by the rotation interlock S1 of the rotation plate 46 and the The direction of the irradiation port 45 can be adjusted by the hinge interlocking S2 of the support base 462 so as to be irradiated.

As shown in FIG. 5B, when a wider range of irradiation is required, the irradiation unit 45 irradiates the reflection plate 441 in the direction of the reflection plate 441 and irradiates ultraviolet rays in a wider area by a reflection plate 441 forming a curved surface. Can be achieved. In this case as well, the direction of the irradiation aperture 45 is adjusted by the interlocking rotation S1 of the rotation plate 46 and the hinge interlocking S2 of the support base 462 so that the area reflected by the reflection plate 441 can be selected .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

1: System 2 of the present invention: Lighting module
3: Individual module 4: Individual survey module

Claims (6)

An illumination module including an illumination LED for illuminating illumination in the space and an ultraviolet LED for irradiating ultraviolet light, a control unit for controlling the illumination LED and the ultraviolet LED, and a first communication unit; And a controller for controlling the ultraviolet ray accumulation amount of the user based on the ultraviolet ray index detected by the detecting unit and analyzing the derived ultraviolet ray accumulation amount and user information of the data unit, And an individual module including an analysis unit for deriving control information and a second communication unit for transmitting the ultraviolet LED control information derived from the analysis unit to the first communication unit,
The analyzer compares the ultraviolet accumulation amount of the user with the critical ultraviolet accumulation amount of the user stored in the data portion and derives a warning signal when the ultraviolet accumulation amount of the user exceeds the critical ultraviolet accumulation amount. Lt; / RTI >
And a third communication unit configured to receive ultraviolet LED control information derived from the analyzing unit through a second communication unit, wherein the third communication unit is configured to receive the ultraviolet LED control information from the second communication unit, An individual irradiation module including a second control unit for controlling the second ultraviolet LED,
Wherein when a plurality of users are present in the space, a warning signal is generated in the personal module of some users, and the ultraviolet LED of the lighting module is turned off, the second ultraviolet LED is turned on.
delete The method according to claim 1,
Wherein the personal module is configured in a wearable device, and the wearable device includes a display unit on which the warning signal can be displayed.
delete delete The method according to claim 1,
The individual irradiation module may include an irradiation unit having a second ultraviolet LED and irradiating ultraviolet rays, a connecting hole formed on the lower surface of the irradiation hole and including a rotating plate for allowing the irradiation port to rotate and interlocking with rotation, and a supporting base hinged to the rotating plate, And a body connected to the second communication unit and the second control unit and having a recessed reflector formed on the upper surface thereof and connected to the support.

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