KR102016411B1 - Whole body cryo therapy and light therapy - Google Patents

Abstract

The present invention relates to a cryogenic and light body managing apparatus. More specifically, the present invention relates to the cryogenic and light body managing apparatus comprising: a chamber formed a space therein; a cold air supply unit for supplying a gas refrigerant into the chamber; and a light source unit formed on an inner wall of the chamber to irradiate light to the inside, thereby being able to perform both cryotherapy and light therapy in one apparatus.

Description

Ultra-low temperature and full-body light management device {WHOLE BODY CRYO THERAPY AND LIGHT THERAPY}

The present invention relates to an ultra-low temperature and light systemic body care device, and more particularly, to a systemic body care system that implements a combination of whole body cryo therapy and whole body light therapy using a single body care device. It is about.

In modern times, various means are disclosed to promote people's health. Among them, therapies including light therapy or cryotherapy are recently advanced, so that the effects are amplified in a shorter time.

The cold therapy has been used in the past as a method of cold compressing the user's topic, such as ice towels and ice packs, and in modern times it is being used as a device to supply the cryogenic cooling gas to the whole body of the subject. Such a cryogenic device is disclosed in Korea Patent Publication No. 10-1642451 ("Cryogenic Device"), cold treatment is pain relief, inflammatory treatment, muscle relaxation, through activation of autoimmune function by increasing blood circulation, It helps improve the quality of life by activating the effects of injury recovery, skin soothing and skin disease improvement, relief of depression and anxiety disorder.

The light therapy (Phototherapy) is a re-lighted therapy by Niels Ryberg Finsen, a Nobel Prize-winning recipient of medicine in 1903, to alleviate acne through physiochemical reactions as light of a certain wavelength is efficiently absorbed by specific pigments in cells. It helps to restore skin by activating the effects of releasing inflammation, relieving pain, strengthening UV resistance, preventing scars and pigmentation, and improving skin tone. And NASA has begun using LEDs to grow plants in space. In the process, they found that LED light had an effect of activating animal cells, and since then, treatments have been actively developed.

Apparatus using light therapy as described above is disclosed in various documents, including Korean Patent Publication No. 10-2013-0063053 ("Sleeping Capsule"). However, as shown in FIG. 1, the conventional devices, as shown in FIG. 1, provide light / color therapy in combination with a phytoncide supply part 2 and an oxygen supply part 3 that provide convenience to a user by providing fragrance or fresh air in the capsule 1. (4) is used.

That is, the currently disclosed technology does not disclose a systemic manager including a cold therapy including a pain relief effect of a user and a light therapy including a skin disease improvement effect of a user. Accordingly, the user must separately provide a device that provides each therapy, and as a plurality of devices are disclosed, it is difficult to popularize using a lot of space.

KR 10-1642451 B1 (“Cryogenic Devices”) 2016.07.25. Announcement KR 10-2013-0063053 A ("Sleeping capsule") 2013.06.14. open

The present invention has been made to solve the above problems, an object of the present invention is to provide a cold therapy (Cryo Therapy) and light therapy (Cryo Therapy) to the user through one device containing a cryogenic cold air supply and a plurality of light rays It relates to a cryogenic and ray systemic device that is formed to provide all of the effects).

Ultra low temperature and the whole body light ray management device of the present invention for achieving the above object, a chamber formed therein; A cold air supply unit supplying a gas refrigerant into the chamber; And a light source unit formed on an inner wall of the chamber to irradiate light to the inside.

In this case, the light source unit may include a plurality of unit light sources formed in different wavelength regions.

In addition, the unit light source may be selected from among IR LEDs, Red LEDs, Green LEDs, Blue LEDs, and Yellow LEDs.

The light source may include a plurality of LED bars having a length formed vertically and disposed along the inner circumferential direction of the chamber, and at least one LED bar may include a plurality of unit light sources having the same wavelength range. have.

The light source unit may include a unit light source controller connected to one or a plurality of LED bars adjacent to each other, and the unit light source controller may be turned on / off using a duty ratio for individual unit light sources on at least one or more LED bars. It may be characterized by controlling the skin improvement effect by turning off, brightness control, or frequency.

In addition, the present invention is the upper portion of the chamber is formed with an opening opening, one side of the chamber is formed to open and close the door, the other side of the chamber is provided with the cold air supply unit, the light source is the inner wall circumferential direction of the chamber It may be characterized by including a plurality of unit light source arranged along.

And the ultra low temperature and the whole body light management device of the present invention can be characterized in that it is operated by the ultra low temperature whole body management, or the ultra low temperature whole body management in the light whole body management in the order of the individual or convenience according to the selection of the operator and the user. .

In addition, the whole body management system of the present invention, the ultra-low temperature and the ray whole body management device; An internal sensor unit disposed in the chamber to measure at least one or more environmental information among temperature, humidity, and oxygen concentration; An external sensor unit disposed at an upper side of the chamber and measuring at least one or more environmental information of temperature, humidity, and oxygen concentration; and including a gas refrigerant supplied from the cold air supply unit according to a temperature measured by the internal sensor unit. The amount is adjusted, the operation of the cold air supply unit may be stopped when the oxygen concentration and humidity measured by the internal sensor unit or the external sensor unit is less than the reference value.

The whole body management system of the present invention may be characterized in that the light source unit is operated when the cold air supply unit is stopped.

In addition, the whole body management system of the present invention is the ultra-low temperature and the ray whole body management device; A sensor unit provided in the chamber to measure at least one or more environmental information among temperature, humidity, and oxygen concentration; At least one camera photographing the interior of the chamber; And a first external monitor disposed above the chamber, wherein the environmental information measured by the sensor unit and the image captured by the camera are output from the first external monitor, and the first external monitor is an input module. Is formed, the cold air supply and the light source may be controlled according to the information applied from the input module.

The camera may include a thermal imaging camera. When a color set in the image photographed by the thermal imaging camera is displayed, the operation of the cold air supply unit may be stopped and the light source unit may be operated.

In addition, the whole body management system of the present invention is ultra-low temperature and light systemic body care; And a control device for controlling the operation of the light source unit, wherein the control device operates a plurality of light sources according to input data, and in the case of a single mode, a light source having one wavelength region selected is moved into the chamber. In the composite mode, a plurality of light sources having different wavelength ranges may be irradiated to the inside of the chamber.

In addition, the whole body management system of the present invention is ultra-low temperature and light systemic body care; And a whole body management program operating the cryogenic and ray whole body manager; wherein the whole body management program is capable of collecting and storing user information, and is recommended according to a user's ultra low temperature whole body management and light whole body management usage pattern. It may be characterized by including a function for proposing a program and informing the arrival of the visit cycle.

Ultra-low temperature and light systemic body management of the present invention by the configuration as described above, the cold air supply for cryotherapy (Cryo Therapy) and the light source for light therapy (both light therapy) are both included in the user to a variety of devices Can be provided to enjoy the effect. If the cold air supply unit is operated first, and then the light source unit is operated, skin therapy is possible with the temperature increase inside the chamber, and if the cryotherapy is performed after light therapy, the change in body temperature is more extreme. Degradation leads to the advantage to maximize the effect.

In addition, the present invention, when using an ultra-low temperature gas refrigerant, the internal gas is discharged to the outside and the temperature inside the chamber through the light source unit while stopping the operation when the low body temperature below the reference occurs or the humidity is excessively high to the user By doing so, there is an advantage that the function of dealing with accidents is further improved.

In addition, the present invention has the advantage that the user can enjoy a variety of effects through a single device according to the purpose of skin improvement by operating in different modes using light sources in different wavelength ranges. In addition, since a plurality of unit light sources of the same wavelength region are provided on the LED bar, there is an advantage in that maintenance is more easily performed by replacing the corresponding LED bar in case of failure.

1 is a ray telegraph manager according to the prior art of the present invention.
Figure 2 is a schematic diagram showing the operation of the cryogenic whole body manager according to an embodiment of the present invention.
Figure 3 is a control system configuration of the cryogenic whole body manager according to an embodiment of the present invention.
Figure 4 is a control system configuration of the cryogenic whole body manager according to another embodiment of the present invention.

Hereinafter with reference to the accompanying drawings will be described in detail the ultra-low temperature and light telegraph manager according to various embodiments of the present invention. The drawings introduced below are provided by way of example so that the spirit of the invention to those skilled in the art can fully convey. Therefore, the present invention is not limited to the drawings presented below and may be embodied in other forms. Also, like reference numerals denote like elements throughout the specification.

At this time, if there is no other definition in the technical terms and scientific terms used, it has the meaning that is commonly understood by those of ordinary skill in the art to which this invention belongs, and the gist of the present invention is unnecessary in the following description and the accompanying drawings Descriptions of well-known functions and configurations that may be blurred are omitted.

2 and 3 are related to an embodiment of the present inventors cryogenic and light systemic telescope, FIG. 2 is a plan view of the inside of the cryogenic systemic telescope of the present invention, and FIG. 3 is a plan view of the cryogenic telegraph system, respectively.

First, referring to FIG. 2, the cryogenic and ray telegraph manager of the present invention includes a chamber 100 having a space A formed therein, a cold air supply unit 200 for supplying a gas refrigerant into the chamber 100, and the chamber. It is formed on the inner wall of the 100 may include a light source unit 300 for irradiating light inward.

The chamber 100 may have an opening 110 formed at an upper portion thereof and a door 120 that may be opened and closed at one side thereof. Accordingly, the user may open the door 120 to enter the space A, and when the door 120 is closed, a part of the upper body of the user (for example, the neck) may be exposed to the outside. In addition, the chamber 100 may have an electric lift 130 formed below the space A, and move up and down according to the user's body so that the user's respirator portion may be exposed to the outside.

In this case, the electric lift 130 may be formed in various forms. For example, a scissor lift employing a mechanical driving method such as a ball screw may be used for a longer period of time even under repeated cooling and thawing conditions. May be provided. The electric lift 130 may be automatically driven when the user's body is measured through a sensor or the user inputs his or her own key, or may be manually adjusted up and down through compatibility with a separate switch. Can be provided. At this time, the present invention may further include a motor (M) to drive the electric lift (130).

The cold air supply unit 200 may include a cooler 230 and a cold air circulation fan 240. The cooler 230 may be configured to supply gas refrigerant to the inside of the chamber 100, and may further include a valve for controlling the discharge of the gas refrigerant. And it may include a nozzle for discharging, the nozzle may be configured to supply to at least one or more points selected from the top, the middle and the bottom of the chamber 100.

In this case, when the cold air supply unit 200 is used to vaporize the liquid refrigerant, the cold air supply unit 200 may include a liquid refrigerant tank and a vaporizer for vaporizing the liquid refrigerant supplied from the liquid refrigerant tank, the cooler 230 may receive gas refrigerant from the vaporizer and supply the gas refrigerant to the space A of the chamber 100. In this case, the liquid refrigerant may use various fluids such as liquid nitrogen, liquefied helium, and liquid carbon dioxide in an ultra low temperature state. In this case, it may be preferable to use a liquid refrigerant that is stored in a liquid state having a small volume since the boiling point is a cryogenic temperature as a substance present as a liquid under an ultra low temperature environment. Accordingly, as the refrigerant is evaporated, the volume is expanded, so it is easy to form a large space in a cryogenic state even with a small amount of fluid.

The liquid refrigerant tank may also be configured to supply an appropriate amount to the vaporizer, including a control valve. At this time, the control valve can minimize the impact of the pressure by using the maximum operating pressure is higher than the maximum operating pressure of the liquid refrigerant tank. In addition, the vaporizer may be configured in a variety of quantities of the inlet and outlet of the pipe shape and length so that the supplied liquid refrigerant is vaporized. In addition, the carburetor may be made of a high rigidity and high thermal conductivity, such as copper tube or stainless steel. In addition, the vaporizer may be located inside the cooler, and is located in an appropriate size and shape in consideration of the cryogenic temperature, cooling efficiency, and cold holding time to be used, and the number of discharge holes compared to the inlet for vaporization pressure and vaporization efficiency By installing the same or more than the inlet may be provided to smoothly discharge the cryogenic cooling gas according to the pressure difference. The above-described control valve, carburetor and cooler may be provided with a strainer or the like to minimize the impact caused by pressure. In addition, the cooler 230 may be made of a material having high rigidity and corrosion resistance, and the cooler 230 may be formed of a heat insulating material to be sealed but prevent heat exchange with the outside.

The cold air circulation fan 240 may include a single or a plurality of fans, and one or more positions selected from the top, the middle, and the bottom of the space A of the chamber 100 as described above according to the circulation of the cooler. Can be placed in. In addition, when a plurality of fans of the cold air circulation fan 240 are provided, gas refrigerant inside the chamber 100 may be circulated through individual or group control. In this case, the cold air circulation fan 240 increases the flow rate to the cooler 230 that preserves the gas refrigerant vaporized through the control valve and the vaporizer, and sends the cryogenic cold air into the space A of the chamber 100 through the cold air supply hood. It functions to improve cold preservation efficiency by circulating the cold air lost through the function and the upper part of space (A) to the lower part or the middle part, and at the same time, complements the safety of gas refrigerant. In addition, the cold air circulation fan 240 may prevent an accident due to suffocation by supplying oxygen that is excessively lost through the opening 110 of the chamber 100 to the bottom again.

In addition, the control valve provided in the cooler 230 or the control valve 211 connected to the liquid refrigerant tank may be provided to finely control the discharge amount, and may be provided to adjust the nitrogen discharge amount by dividing into 100 steps. Can be. And when the nitrogen pressure is high, the control function to reduce the discharge sound of nitrogen through the control valve 211 can be combined. Accordingly, the present invention can provide the apparatus in various forms such as nitrogen-saving cold air supply mode and cryogenic maintenance cold air supply mode by adjusting the cold air supply unit 200 according to a set temperature. At this time, it may be made to adjust the discharge of the control valve and the fan power of the cold air circulation fan 240 according to the provided mode.

The light source unit 300 may include a plurality of unit light sources 311 formed in different wavelength regions. In this case, the unit light source 311 may include at least one or more selected from IR LED, Red LED, Green LED, Blue LED, and Yellow LED, and may be expressed in other colors combining RGB in addition to the above-mentioned color. It may be. For example, the blue LED may have a wavelength region of 405 nm to 415 nm, green to 416 nm to 525 nm, yellow LED to 526 nm to 590 nm, red LED to 630 nm to 660 nm, and IR LED to 800 nm to 900 nm, respectively. In addition, the light source unit 300 may be configured to include other wavelength regions not illustrated herein. In addition, the present invention may be provided so that various kinds of light sources are sequentially arranged along the circumferential orientation, or in place of the appropriate light source in consideration of the user's body. For example, the present invention may be provided in the same wavelength region with respect to the whole body, or unit light sources 311 such as IR, blue, red, and green may be disposed differently according to body parts such as legs and back arms. Each of the LEDs may be provided to adjust a duty ratio, and for example, a light amount may be adjusted by adjusting a duty ratio between 0 and 100. The LEDs may be operated at a frequency setting between 50 Hz and 500 Hz, and may be provided to adjust the degree of skin application of the LED together with the aforementioned duty ratio.

Here, users can enjoy various effects according to each wavelength range. For example, Blue LED (405nm ~ 415nm) and Green LED (416nm ~ 525nm) are used for acne treatment and wrinkle improvement, and Yellow LED (526nm ~ 590 nm) is used for whitening. , Red LED (630nm ~ 660nm) can be used for skin regeneration, IR LED (800nm ~ 900nm) can be used for treating yellow spots. The present invention can not only select the LEDs that are operated to be used interchangeably with the above-described effects, but also induce the user to output and select the desired effects on the display. Accordingly, when the user selects the desired effect, the light source unit 300 may be configured to control the light source unit 300 by using a preset movable area and order matching with the corresponding effect and a light quantity value.

In addition, the light source unit 300 has a length is formed up and down, and includes a plurality of LED bars 310 disposed along the inner circumferential direction of the chamber 100, the at least one LED bar 310 has the same wavelength range The plurality of unit light sources 311 may be arranged. In addition, the unit light source 311 may be arranged in a plurality in the vertical direction on the LED bar 310, it may be configured to be arranged in two dimensions in a plurality of arranged in the left and right directions.

The light source unit 300 may include a unit light source control unit 321 connected to one or a plurality of LED bars 310 adjacent to each other, and for individual unit light sources 311 on one LED bar 310. The unit light source control unit 321 may be configured to turn on / off. In addition, the unit light source control unit 321 may also be provided with a plurality of light source control unit 320 to integrate it, the light source control unit 320 may be connected to the control device 600. Accordingly, the present invention may be configured to individually operate the unit light source 311 through the light source control unit 320 and the unit light source control unit 321 according to data input to the control device 600. In addition, the unit light source 311 is distinguished by the LED bar 310, the unit light source control unit 321 may be provided to facilitate the maintenance by adjusting the LED bar 310 adjacent to each other. In addition, the aforementioned duty ratio can be adjusted in units of the unit light source control unit 321, thereby saving energy and amplifying the effect.

The present invention may further include a gas discharge unit 500 including a blower 510 and an exhaust pipe 520. The gas discharge part 500 may be composed of an exhaust pipe 520 communicating with the space A and the outside of the chamber 100 and a blower 510 disposed on the exhaust pipe 520, and appropriately managed during the management. It can be used in a variety of situations, such as to maintain the temperature or to operate in emergency situations to promote user safety. In addition, the gas discharge unit 500 may be made to discharge for humidity management when the humidity of the gas refrigerant in the chamber 100 is excessive. The present invention may further include an external air supply unit for supplying the outside air into the chamber 100 to control the temperature and humidity in an emergency.

In addition, the present invention is disposed outside the first external monitor 621 and the chamber 100 is provided for use by the user in the management, before or after use or other personnel can observe the state of the chamber 100 And a second external monitor 622. In this case, the first external monitor 621 may be disposed on the opening 110 of the chamber 100, and the user may be configured to observe the environmental state or the current progress of the interior of the chamber 100 in real time during management. Can be. In addition, the first external monitor 621 and the second external monitor 622 may include an input module as well as an output device such as a display. Accordingly, the user may be configured to be managed by selecting one of service menus provided such as a management time, a management temperature, a type of light source, and the like. In this case, the present invention may stop the operation of the cold air supply unit 200 under an emergency situation in which an emergency stop button is formed inside or outside the chamber 100 during management.

Next, referring to FIG. 3, the chamber 100 may further include an electric blind 140 formed on the opening 110. The electric blind 140 may include a function of preserving an internal temperature by closing the upper end at the time of operating the whole body manager. Accordingly, there is an advantage that can reduce the amount of nitrogen by minimizing the time of pre-cooling. In addition, the electric blind 140 may maintain an appropriate oxygen concentration by adjusting the amount of gas refrigerant discharged to the upper side of the chamber 100.

In addition, the present invention may include a sensor unit 400 including an internal sensor unit 410 disposed inside the chamber 100 and an external sensor unit 420 disposed outside the chamber 100. . The internal sensor unit 410 and the external sensor unit 420 may be configured to measure at least one or more of temperature, humidity, and oxygen concentration, respectively. In the case of the temperature measured by the internal sensor unit 410, the temperature of the gas refrigerant supplied from the cooler 230 to the interior of the chamber 100, the temperature of the upper, middle or lower end of the interior of the chamber 100, etc. Can be measured. In addition, the external sensor unit 420 may be installed near the user's respirator in the opening 110 of the chamber 100, and suffocate by measuring the humidity and oxygen concentration of the gas discharged from the inside of the chamber 100. It may be provided to prevent accidents, such as frostbite. Of course, the internal sensor unit 410 may also include a sensor for measuring oxygen concentration to measure the air quality of the gas inside the chamber 100. At this time, the present invention may include a control device 600 for controlling the above-described configuration as a whole, the whole body management system through the control device 600 will be described later with reference to FIG.

Figure 4 relates to an embodiment of the whole body management system using the ultra-low temperature and light telegraph management of the present invention, Figure 4 shows the configuration of the whole body management system.

Referring to FIG. 4, the present invention may be configured to include a control device 600. The control device 600 is connected to the electric lift 130 and the electric blind 140 described above to input data. The control command may be configured to be performed accordingly. In addition, the control device 600 is connected to the control valve 211 and the cold air circulation fan 240 of the cold air supply unit 200 may be configured to adjust the amount of nitrogen discharged or purified in the chamber 100. . The control device 600 may be connected to input devices including an internal sensor unit 410, an external sensor unit 420, and a camera 610, and may include an internal monitor 620 and a first external monitor 621. And an output device including a second external monitor 622.

Accordingly, the control device 600 may control the entire apparatus through input signals measured by the internal sensor unit 410, the external sensor unit 420, and the camera 610, and the internal monitor 620. The controller may be configured to be controlled through a signal input from an input module of the first external monitor 621 and the second external monitor 622. This will be described in more detail as follows.

First, the present invention may determine whether at least one of temperature, humidity, and oxygen concentration measured in real time by the internal sensor unit 410 and the external sensor unit 420 reaches a reference value. When the user inputs the operating temperature, the reference humidity value and the reference oxygen concentration input through the input module, the control device 600 is a temperature inside the chamber 100 measured by the internal sensor unit 410 to the operating temperature The operation of the cold air supply unit 200 may be controlled by determining whether it has reached. In this case, when the internal temperature of the chamber 100 measured by the internal sensor unit 410 is lower than or close to the set value, the cold air supply unit 200 may be configured to reduce or not supply the supply amount of gas refrigerant. When the humidity measured by the internal sensor unit 410 and the external sensor unit 420 is higher than the reference humidity value, the user may be caught in frostbite by freezing, so that the gas discharge unit 500 may be operated to operate the chamber ( 100 is provided to discharge the gas inside to the outside can control the operation of the cold air supply unit 200. In addition, when the oxygen concentration measured by the internal sensor unit 410 and the external sensor unit 420 is below a predetermined level, the electric lift 130 is driven upward to allow the user to inhale fresh outside air or the chamber ( It may be provided to open the door of 100) to promote the safety of the user. Alternatively, as described above, a separate gas supply unit may be provided to operate the fan of the gas supply unit to supply fresh outside air to the inside of the chamber 100. In addition, the camera 610 may be provided to observe the inside of the chamber 100. When the camera 610 is a thermal imaging camera, it is determined that the user's body temperature is out of a set color and the door is in an emergency state. Opening or operating the electric lift 130 or through the gas supply and the gas discharge may be selected from the fresh outside air introduced and the internal cryogenic fluid discharge. In this case, the control device 600 may be provided to adjust the light source unit 300, and when the user has a low body temperature, the light source unit 300 is operated to increase the internal temperature of the chamber 100. It may be provided to.

The present invention may provide a whole body management system in which cryotherapy and light therapy are simultaneously performed through the cold air supply unit 200 and the light source unit 300. In this case, when the cold air supply unit 200 is operated first, the light source unit 300 may be provided to operate after the set time. Accordingly, the light source unit 300 may increase the internal temperature of the chamber 100 or supply heat to the user, thereby preventing the user from being exposed to a sudden environmental change after using the device. In addition, the whole body management system of the present invention may be configured such that the light source unit 300 is pre-operated and the cold air supply unit 200 is later operated. In such a case, the cold air supply unit 200 is operated in a state in which the user's body temperature is increased through the light source unit 300, thereby causing a sudden decrease in body temperature, thereby increasing the effect of cold therapy. In this case, the whole body management system of the present invention may be configured in various modes such that the cold air supply unit 200 and the light source unit 300 are operated simultaneously with each other, or the operation time is partially overlapped or alternately formed.

In addition, the control device 600 operates a plurality of light sources according to the input data, in the case of a single mode is made so that the light source having one wavelength region selected is irradiated to the inside of the chamber 100, In this case, the plurality of light sources having different wavelength regions selected may be configured to be irradiated to the inside of the chamber 100. For example, it may include a function of setting each maximum value that can be applied when multiple LEDs are applied in a complex mode. As an example, the total number of applications that can be applied to all LEDs is 100, so that up to 80 can be set for each LED. Here, some are fixed so that the IR LED is assigned to 20 by default, and the sum of other RED, GREEN, BLUE, and YELLOW can be set to 80. If RED (60), GREEN (20) is set based on the IR LED (20), both BLUE and YELLOW may not be operated to 0 afterwards. As another example, a method of operating all LEDs may be set to IR LED 20 + RED (20) + GREEN (20) + BLUE (20) + YELLOW (20).

Here, the whole-body management system of the present invention may be provided with a sensor that can measure the degree of light therapy on the internal sensor unit 410 or the external sensor unit 420. In addition, the camera 610 may include a fixed or mobile microscope device to measure the skin condition of the user before and after using the device. At this time, the image measured by the camera 610 is configured to be output to any one selected from the internal monitor 620, the first external monitor 621 and the second external monitor 622, or through a communication module It may be configured to be stored in the server DB.

In addition, the whole-body management system of the present invention includes a whole-body management program for operating the ultra low temperature and the ray full-body manager, the whole-body management program, the ability to collect and store the user's information, the ultra-low temperature whole body management and the ray whole body of the user It may be characterized by including a function to suggest a recommended program according to the management use pattern and to notify when the visit cycle arrives. Accordingly, the telegraph management system has an advantage that it can be provided more easily for the main function that the user needs. In this case, collecting the user information may be possible to authenticate and collect through wireless communication, such as RFID, may be provided in the form of an application to the terminal with the user to connect to the server.

As described above, the present invention has been described by specific embodiments such as specific components and the like, but the embodiments are provided in order to help a more general understanding of the present invention, and the present invention is limited to the above embodiment. However, various modifications and variations are possible to those skilled in the art to which the present invention pertains.

Accordingly, the spirit of the present invention should not be limited to the described embodiments, and all claims having equivalent or equivalent modifications to the claims as well as the following claims are intended to be included in the scope of the spirit of the present invention. will be.

100: chamber
110: opening 120: door
130: electric lift 140: electric blind
200: cold air supply unit
210: liquid refrigerant tank 211: control valve
220: vaporizer 230: cooler
240: cold air circulation fan
300: light source
310: LED bar 311: unit light source
320: light source control unit 321: unit light source control unit
400: sensor
410: internal sensor unit 420: external sensor unit
500: gas discharge unit
510: blower 520: exhaust pipe
600: controller
610: Camera
620: internal monitor
621: first external monitor 622: second external monitor

Claims (11)

A chamber having a space formed therein; A cold air supply unit supplying a gas refrigerant into the chamber; And a light source unit formed on an inner wall of the chamber to irradiate light inwardly;
A sensor unit provided in the chamber to measure at least one or more environmental information among temperature, humidity, and oxygen concentration;
At least one camera photographing the interior of the chamber; And
A first external monitor disposed above the chamber;
Including;
The environmental information measured by the sensor unit and the image taken by the camera is output from the first external monitor,
The first external monitor is formed with an input module, the cold air supply and the light source is controlled according to the information applied from the input module,
The camera comprises a thermal imaging camera,
When the color set in the image taken by the thermal imager is expressed, the operation of the cold air supply unit is stopped and the light source unit is operated.
The method of claim 1,
The cryogenic and ray telegraph manager,
A whole body management system comprising a plurality of unit light sources formed in different wavelength ranges.
The method of claim 2,
The unit light source,
Full-body management system, characterized in that the LED of the other wavelength range is additionally selected based on one or more LED selected from IR LED, Red LED, Green LED, Blue LED and Yellow LED.
The method of claim 2,
The light source unit
A length is formed up and down, and includes a plurality of LED bars disposed along an inner circumferential direction of the chamber,
The at least one LED bar is a whole body management system, characterized in that a plurality of unit light source of the same wavelength region is arranged.
The method of claim 4, wherein
The light source unit,
It includes a unit light source control unit connected to one or a plurality of adjacent LED bar,
Full-body management, characterized in that for the individual unit light source on the at least one LED bar, the unit light source control unit to control the skin improvement effect by changing the on / off or brightness control, frequency using a duty ratio (Duty Ratio) system.
The method of claim 1,
The cryogenic and ray telegraph manager,
The upper portion of the chamber is an open opening is formed,
One side of the chamber is formed with an openable door,
The cold air supply unit is disposed on the other side of the chamber,
And the light source unit includes a plurality of unit light sources arranged along the inner wall circumferential direction of the chamber.
The method of claim 1,
The sensor unit may include an internal sensor unit disposed inside the chamber and measuring at least one or more environmental information among temperature, humidity, and oxygen concentration; And an external sensor unit disposed at an upper side of the chamber to measure at least one or more environmental information among temperature, humidity, and oxygen concentration;
Including;
According to the temperature measured by the internal sensor, the amount of gas refrigerant supplied from the cold air supply is adjusted,
The whole body management system, characterized in that the operation of the cold air supply is stopped when the oxygen concentration and humidity measured by the internal sensor unit or the external sensor unit is less than the reference value.
delete delete delete The method of claim 1,
A telegraph management program operating the cryogenic and ray telegraph manager;
More,
The whole body management program,
A system for collecting and storing user information, and a function for suggesting a recommended program according to a user's cryogenic whole body care and light body care usage patterns and informing the user of the visit cycle.

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