KR101923569B1 - Optical immunotherapy using UV LED - Google Patents

Abstract

The present invention relates to an optical immunotherapy device using a UV light LED. The present invention relates to an optical immunotherapy device using a UV light LED, which comprises a horizontal plate, a lower frame provided at a lower portion of the horizontal plate and a space, A penetrating portion formed in the center portion in the longitudinal direction, the penetrating portion including a main body composed of an upper frame opened and closed by a lid and a front panel and a rear panel installed on front and rear surfaces of the horizontal plate, A guide bracket installed at a predetermined height on the upper surface of the horizontal plate so as to face the side center of the quartz cuvette tube which is seated on the guide bracket, Yubei LED to investigate Lee's ultraviolet rays Characterized in that configured to include a module.

Description

[0001] Optical immunotherapy using UV LED [0002]

The present invention relates to an optical immunotherapy device for enhancing the immunity of blood using a UV light LED.

Generally, the optical immunotherapy device is a new concept anti-aging treatment device using photon therapy. However, blood is collected by 50 ~ 80 cc, then oxygen is injected, ultraviolet rays are irradiated at a constant speed, It is used in a way of transfusion.

These optical immunotherapy devices will purify the blood by eliminating the wastes on the surface of red blood cells and white blood cells. The purified blood is expected to improve the blood circulation, improve the function of the metabolism, improve the immune system and improve the hormone balance .

On the other hand, ultraviolet rays (UV, ultraviolet rays) can be divided into UV-A, UV-B and UV-C when they are photographed with a spectrum of sunlight.

Ultraviolet UV-A has a wavelength range of 320 to 400 nm, is not absorbed into the ozone layer, and has a smaller amount of energy than UV-B, but it can scratch the skin. UV-B is the main actor in burning skin, but UV-A not only makes skin tick, but also acts on skin's immune system and can cause long-term skin damage due to skin aging. Recently, studies have reported that the risk of developing skin cancer is the same as that of UV-B if the UV-A exposure time is long enough to smear the skin. When the ultraviolet rays reach the human body, they are absorbed under the skin layer. In order to protect the skin from this harmful ray, a human immune function is activated. For example, when exposed to ultraviolet light, some cells produce melanin, which absorbs some of the ultraviolet light. Therefore, people who produce less melanin, such as Caucasians, have fewer natural shields against UV-B.

Ultraviolet UV-B has a wavelength range of 280-320 nm, most of which is absorbed by the ozone layer, but some reach the surface. UV-B burns the skin of an animal, penetrates skin tissue and sometimes causes skin cancer. Most of the causes of skin cancer are related to exposure to sunlight and UV-B. UV-B also activates pro-vitamin D in the skin and converts it to vitamin D, which is essential for the human body.

Ultraviolet UV-C has a wavelength range of 100 to 280 nm and is completely absorbed by the ozone layer. UV-C causes chromosomal aberrations, kills single-cell organisms, and damages the cornea of the eye. Fortunately, this range of ultraviolet light, known as UV-C, is almost all absorbed by stratospheric ozone.

The lamp used for sterilization using the UV-C wavelength is a UV lamp. In the UV lamp, the inside of the quartz tube is evacuated. After the evacuation process is performed through heating, a mixed gas such as mercury is sealed inside. A quartz tube connection nozzle is provided around both ends of the quartz tube to constitute a leakage preventing sealing structure of the fluid through the inner reactor.

In addition, the power cable at both ends of the UV lamp is configured to be connected to a power supply ballast (not shown) to be supplied with power.

On the other hand, such a UV lamp is used in an optical immunotherapy apparatus, and a quartz cuvette tube connected to both ends of a tube through which blood moves between UV lamps is irradiated to irradiate blood passing through the quartz cuvette tube with UV- Cleanse.

However, there is a problem in that such a UV lamp is not suitable for medical use because it is harmful when mercury contained in a quartz tube is exposed to a human body.

Korean Patent No. 10-1061004 (Published on September 1, 2011)

Disclosure of Invention Technical Problem [8] The present invention is directed to an ultraviolet irradiating apparatus for irradiating ultraviolet rays for purifying blood through an optical immunotherapy apparatus, comprising a UV-C LED which does not use mercury, And to provide an optical immunotherapy device using a YBIC LED that can be used safely.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not intended to limit the invention to the precise form disclosed. It can be understood.

According to a preferred embodiment of the present invention, there is provided a plasma display panel comprising a horizontal plate, a lower frame installed at a lower portion of the horizontal plate, and a space formed at an upper portion of the horizontal plate, A quartz cuvette tube installed on both sides of the upper surface of the horizontal plate at both sides in the longitudinal direction and in which the blood is moved, a main body including an upper frame opened and closed by a cover, a front panel and a rear panel installed on front and rear surfaces of the horizontal plate, A guide bracket having both ends thereof held at a predetermined height and a YUVEC LED module installed at a predetermined height on the upper surface of the horizontal plate and irradiating ultraviolet rays to the side center of the quartz cuvette tube which is seated on the guide bracket, .

More preferably, the UV LED module may comprise a plurality of UV LED elements for irradiating ultraviolet light having a wavelength range of 250 to 280 nm.

More preferably, the UV LED module may be installed on both sides of the quartz cube tube opposite to each other.

More preferably, the YUV LED module may be installed so that the distance between the YUV LED modules can be adjusted toward or away from the quartz cuvette tube.

Preferably, the plurality of UBS LED devices mounted on the UBS LED module are mounted while maintaining a constant spacing along the longitudinal direction so as to correspond to the quartz cube tube, The UV range of ultraviolet rays irradiated to the quartz cuvette tube in the LED device may not be separated from each other.

More preferably, the YBIC LED device mounted on the YBIC LED module may be constituted by one or more rows.

A pair of first auxiliary UV LED modules may be provided on the upper side of the horizontal plate so that ultraviolet rays can be radiated in a diagonal direction facing the quartz cuvette tube.

The second auxiliary UV LED module may be provided on the upper surface of the horizontal plate so that ultraviolet rays can be irradiated in a diagonal direction facing the quartz cuvette tube.

The first reflection member may be further provided on both sides of the inner surface of the upper frame so that the ultraviolet rays irradiated from the UV LED module are reflected and irradiated toward the quartz cuvette tube.

The second reflector may be further provided on both sides of the upper surface of the horizontal plate so that ultraviolet rays irradiated from the UV LED module are reflected and irradiated toward the quartz cuvette tube.

The ultraviolet ray sensor may further include a UV sensor for detecting ultraviolet rays irradiated from a UV LED element of the UV LED module facing the upper center of the UV LED module.

More preferably, the UV LED module is divided into sections along the length direction, and the ultraviolet ray sensor may be installed in each divided section.

More preferably, if the accumulated cumulative irradiation time is exceeded and the set light amount is not reached after comparing and measuring the ultraviolet cumulative irradiation time and the amount of UV light irradiated from the UV LED element of the UV LED module, And may be configured to be notified to the user.

More preferably, the replacement time of the LED module may be visually announced through a display lamp provided on the front panel of the main body or may be informed to a user through the generation of a warning sound.

More preferably, both ends of the quartz cube tube are provided with gripping portions, and the gripping portions may be fitted into the guide grooves of the guide bracket.

More preferably, when the detection sensor is provided in the guide groove and the grip portion is incorrectly seated in the guide groove, it is determined that the grip portion of the quartz cuvette tube is incorrectly seated in the guide groove of the guide bracket according to the operation of the detection sensor And inform the user of this.

The optical immunotherapy apparatus using the UBS LED according to the preferred embodiment of the present invention has the following effects.

That is, since the means for generating ultraviolet rays of ultraviolet rays to be used in the optical immunotherapy apparatus is composed of ultraviolet light, it can be used for medical purposes safely as well as being easy to manufacture. If necessary, the wavelength intensity of ultraviolet rays can be controlled, It is possible to expand the versatility and effectively use it.

Here, the effect of the present invention described above is expected to be exerted by the constitution of the contents regardless of whether or not the inventor perceives it. Therefore, the above-mentioned effect is only some effects according to the contents described, Should not be recognized.

Further, the effect of the present invention should be grasped further by the entire description of the specification, and even if it is not stated in an explicit sentence, a person having ordinary skill in the art to which the written description belongs, It should be seen as an effect described in this specification.

FIG. 1 is an exploded perspective view illustrating the structure of an optical immunotherapy apparatus using a UV light LED according to an embodiment of the present invention. Referring to FIG.
FIG. 2 is a perspective view illustrating an optical immunotherapy apparatus using a UV light LED according to an embodiment of the present invention. Referring to FIG.
FIG. 3 is a perspective view illustrating a state in which a UV light LED module and a quartz cuvette tube are installed in a main body of an optical immunoassay using a UV light LED according to an embodiment of the present invention.
FIG. 4 is a plan view illustrating a state in which a UBIS LED module of an optical immune therapy apparatus using a UBS LED according to an exemplary embodiment of the present invention is adjusted in distance from a quartz cuvette tube through a plurality of slots.
FIG. 5 is a plan view showing the relationship between areas irradiated with ultraviolet rays of UV light directed toward the quartz cuvette tube in each UV LED module of the optical immunotherapy device using UV light according to an embodiment of the present invention.
FIG. 6A is a view illustrating an installation state of a UBS LED module and a first auxiliary UBS LED module installed toward a quartz cuvette tube of an optical immune therapy apparatus using a UBS LED according to an embodiment of the present invention.
6B is a view illustrating an installation state of the UBS LED module and the second auxiliary UBS LED module installed toward the quartz cuvette tube of the optical immunotherapy device using the UBS LED according to the embodiment of the present invention.
FIG. 6C is a perspective view of a UBIC LED module installed on a quartz cuvette tube of an optical immune therapy apparatus using a UBCS LED according to an embodiment of the present invention, a first auxiliary UC LED module, and a second auxiliary UC LED module Fig.
FIG. 7A is a view illustrating a state in which a UV light irradiated from a UV light module of an optical immune therapy apparatus using UV light according to an embodiment of the present invention is moved to a quartz cuvette tube through a first reflection member. FIG.
7B is a view illustrating a state in which a UV light irradiated from a UV light module of an optical immunotherapy apparatus using UV light LED according to an embodiment of the present invention is moved to a quartz cuvette tube through a second reflection member.
FIG. 7C shows a state in which UV light irradiated from the UV light LED module of the optical immunotherapy apparatus using UV light according to an embodiment of the present invention is moved to the quartz cuvette tube through the first and second reflection members. Fig.
8A is a view showing an ultraviolet ray detection sensor which is integrally provided in a UV LED module for detecting UV rays irradiated from a UVLED module of an optical immunotherapy device using a UVLED according to an embodiment of the present invention .
FIG. 8B is a diagram illustrating an ultraviolet (UV) detection system installed on the upper side of a quartz cuvette tube, which is separated from the UVC LED module for detecting ultraviolet rays detected by the UVIS LED module of the optical immunotherapy device using the UVIS LED according to an embodiment of the present invention. Fig.
FIG. 8C is a diagram illustrating an ultraviolet (UV) light detection unit installed on a lower side of a quartz cuvette tube, which is separated from a UVC LED module to detect a UV light irradiated from a UV light LED module of an optical immunotherapy device using a UV light LED according to an embodiment of the present invention. Fig.
FIG. 8D is a sectional view of a quartz cuvette tube which is separated from the UV LED module for detecting ultraviolet rays irradiated by the UVIS LED module of the optical immunotherapy device using the UVIS LED according to an embodiment of the present invention. 1 is a view showing an ultraviolet ray detection sensor.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, which are intended to illustrate the present invention in a manner that allows a person skilled in the art to easily carry out the present invention. , And this does not mean that the technical idea and scope of the present invention are limited.

In addition, the sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation, and the terms defined specifically in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user, operator And the definitions of these terms should be based on the contents throughout this specification.

First, components of the optical immunotherapy apparatus using the UBS LED according to the present invention include a main body having a front lower panel and a lower upper frame with a horizontal plate as a center, a front panel and a rear panel mounted on the front and rear, A guide bracket installed on the upper surface of the quartz cuvette tube for supporting the quartz cuvette tube and a UBIC LED module for irradiating the ultraviolet rays toward the quartz cuvette tube. Let's look at it.

First, the main body 100,

As shown in FIGS. 1 and 2, a quartz cuvette tube 600 provided at both ends is provided with a tube through which blood is moved. A quartz cuvette tube 600 is irradiated with ultraviolet (UV) A space in which the UBS LED module 300 is installed and a space in which electric components for operating and controlling the UBS LED module 300 are provided so that blood moving through the cuvette tube 600 can be purified.

The main body 100 is provided with a lower frame 130 so as to have a predetermined size space below the horizontal plate 120 and has a space of a predetermined size above the horizontal plate 120, A front panel 140 and a rear panel 150 are installed on the front and rear surfaces of the horizontal plate 120. The front panel 140 and the rear panel 150 are connected to the upper frame 110 and the lower frame 150, 130, and the main body 100 is formed of a substantially rectangular housing.

A through hole 111 is formed in the center of the upper surface of the upper frame 110 in the longitudinal direction. The through hole 111 is opened and closed by the cover 160.

The lid 160 is hinged to one of the upper frames 110 and is configured to open and close the through-hole 111 through a rotation operation.

3, a guide bracket 200 to be described later is installed at both sides in the longitudinal direction of the upper surface of the horizontal plate 120, and a quartz cube tube is installed in the guide bracket 200.

The position of the guide bracket 200 and the penetration part 111 of the upper frame 110 are configured to be aligned with each other so that the guide bracket 200 is visible when the cover 160 is opened, The quartz cuvette pipe 600 is not visible from the outside when the lid 160 is closed after the quartz cuvette pipe 600 is seated.

A UV light LED module 300, which will be described later, is installed on the upper surface of the horizontal plate 120 so as to irradiate ultraviolet rays toward the quartz cuvette tube 600 mounted on the guide bracket 200.

A door detection sensor (not shown) may be further provided on the upper surface of the horizontal plate 120 to sense opening and closing of the door 160 for safety. (Not shown) provided in the controller 160, and the control unit controls the optical immuno therapy apparatus to be inoperable when the lid 160 is opened.

The front panel 140, which is installed on the front surface of the horizontal plate 120 in the vertical direction as shown in FIG. 2 and is installed with the upper and lower ends of the upper frame 110 and the lower frame 130 being surrounded by the inner surface, Various switches and display lamps for notifying the control and status of the lamps.

The front panel 140 may be provided with a display unit or a speaker so as to inform the control and state of the optical immunity therapy apparatus as required.

The front panel 140 is constituted by an LCD panel as necessary to visually display various information according to operation and error occurrence of the optical immunotherapy device and whether the lid 160 is opened or closed, The operation may be configured to be operated in a touch manner.

The guide bracket (200)

And is installed at the center of the upper surface of the horizontal plate 120 to fix the quartz cube tube 600 described above.

3, the guide brackets 200 are installed on opposite sides of the horizontal plate 120 in the longitudinal direction of the horizontal plate 120, respectively, so that both ends of the quartz cuvette tube 600 can be inserted and fixed from the upper side to the lower side And a guide groove 210 partially opened at an upper side thereof.

The guide groove 210 of the guide bracket 200 may be deformed in various ways corresponding to the shape of both ends of the quartz cube tube 600.

On the other hand, when a foreign substance such as a fingerprint is buried in the quartz cuvette tube 600, the ultraviolet rays of the ultraviolet rays can not be irradiated to the blood passing through the quartz cuvette tube 600 due to such foreign matter, A grip portion 610 is provided.

Therefore, when the grip portion 610 is cylindrical, the guide groove 210 may have a semicircular shape so that the outer periphery of the grip portion 610 may be resiliently fitted around the inner circumference of the guide groove 210 (Not shown) that is recessed inwardly along the outer periphery of the cylindrical grip portion 610 is formed in a ring shape. In another embodiment, a fitting projection (not shown in the figure) is formed on the inner circumference of the guide groove 210, The guide protrusion of the guide groove 210 is inserted into the fitting groove of the grip portion 610 when the grip portion 610 is fitted around the inner circumference of the guide groove 210, It is possible to prevent unnecessary movement of the grip portion 610 fitted to the grip portion 610. [

Further, in order to prevent unnecessary rotation of the gripper 610, a wing-shaped guide projection (not shown in the figure) is formed at the lower periphery of the gripper 610, (Not shown) in which the guide protrusion can be fitted in the center of the periphery of the guide groove 210 so that the guide protrusion is fitted into the guide protrusion guide groove when the gripper 610 is fitted into the guide groove 210 Thereby preventing the grip portion 610 from being unnecessarily rotated in the guide groove 210.

Meanwhile, when the grip portion 610 of the quartz cuvette tube 600 is seated in the guide groove 210 of the guide bracket 200, if the ultraviolet rays of the Yubei's cuvette 600 are correctly irradiated to the quartz cuvette tube 600 Can not.

It is preferable that means for confirming that the grip portion 610 of the quartz cube tube 600 is correctly seated in the guide groove 210 of the guide bracket 200 is provided. When the grip portion 610 is incorrectly seated in the guide groove 210 by providing a sensing sensor such as a pressure sensor or an optical sensor on the periphery of the guide groove 210, So as to inform the user of an incorrect seat.

The Ubiquitous LED module 300,

The upper surface of the horizontal plate 120 is installed at a predetermined height so as to irradiate ultraviolet rays toward the quartz cuvette tube 600.

As shown in FIG. 3, the YUV LED module 300 includes a plurality of YUV LED elements 320 mounted on a PCB substrate 310.

The UV LED element 320, which is supplied with power from a power source (not shown) provided in a front portion of the main body 100 and emits ultraviolet rays, is preferably configured to form a wavelength range of 250 to 280 nm, It is more preferable that it is composed of a 253.7 nm wavelength band.

The UV light LED module 300 preferably has a rectangular shape having a predetermined length so as to correspond to the quartz cuvette tube 600 so as to uniformly irradiate UV light toward the quartz cuvette tube 600 mounted on the guide bracket 200. [ A plurality of YUV LED modules 300 are mounted on the PCB substrate 310 of the YUV laser module 300 so as to face the center of the quartz cube tube 600 in the longitudinal direction.

The YUV LED elements 320 mounted on the YUV LED module 300 may be constituted by one row, but may be constituted by forming a plurality of rows at upper and lower intervals, It may also be a form of discrepancy.

The distance between the YUVELD element 320 and the quartz cuvette tube 600 may be adjusted according to the distance between the YUVELD element 320 and the quartz cuvette tube 600 in setting the interval of the YVUELD element 320 mounted on the YUVELDY module 300. [ The ultraviolet ray irradiation range irradiated to the quartz cube tube 600 in the UV LED element 320 adjacent to the UV LED element 320 may be varied as shown in FIG. It is preferable to adjust the interval of the U, V LED elements 320 so as to meet or overlap with each other so as not to be separated from each other.

It is preferable that the YUV LED module 300 is installed to face the quartz cube tube 600 which is seated on the guide bracket 200 at a predetermined interval on opposite sides in the longitudinal direction.

At this time, according to the specifications of the UBS LED module 320 mounted on the UBS LED module 300, the distance between the UBS LED module 300 and the quartz cube tube 600 can be adjusted The intensity of the ultraviolet rays generated by the ultraviolet LED module 300 may be adjusted.

As shown in FIG. 4, for example, the distance of the YUV LED module 300 may be adjusted by arranging a plurality of slots 121 so as to be parallel to the quartz cube tube 600 at regular intervals on opposite sides of the guide bracket 200 And when the YUV LED module 300 is installed on the upper surface of the horizontal plate 120, the slot 121 or the guide bracket 200, which is close to the quartz cube tube 600 installed in the guide bracket 200, It is possible to control the intensity of the ultraviolet rays of the UV LED module 300 irradiated on the quartz cuvette tube 600 by installing the UV LED module 300. [

The length of the YUV LED module 300 need not be limited to the length of the slot 121 but may be a rail groove (not shown) perpendicular to the quartz cube tube 600 The distance from the quartz cuvette pipe 600 may be adjusted while the UBEC LED module 300 installed at right angles to the rail groove is moved along the rail groove. (Not shown in the drawing) in which the projections can be fitted, and a quartz cuvette tube (not shown) provided in the guide bracket 200 is provided in the horizontal plate 120 The spacing between the YUV LED module 300 and the quartz cube tube 600 may be variously adjusted by providing the YUV LED module 300 in the selected hole at predetermined intervals in a direction away from the YUV lamp module 600.

6A, the upper surface of the horizontal plate 120 may be provided with a pair of U-Flex LED modules 300 on opposite sides of the guide bracket 200, A pair of first auxiliary UV LED modules 300a, which are installed to face the quartz cuvette pipe 600 in a diagonal downward direction so as to face each other, So that the intensity of UV rays can be adjusted through the UV light module and the first UV light module 300a.

In another embodiment, as illustrated in FIG. 6B, a pair of quartz cuvette tubes 600 are installed on the upper surface of the horizontal plate 120 together with the UBS LED module 300 so as to face diagonally upward And the second auxiliary use LED module 300b may be installed together.

As shown in FIG. 6C, the first auxiliary unit LED module 300a and the second auxiliary unit LED module 300b may be installed together with the above-described LED module 300.

On the other hand, reflective members 400a and 400b for reflecting ultraviolet rays of UV rays may be installed so that ultraviolet rays of UV rays may be uniformly irradiated onto the quartz cuvette tube 600.

For example, as shown in FIG. 7A, a first reflecting member 400a may be provided on the upper side of the quartz cube tube 600, and a part of the ultraviolet rays irradiated from the UV- 400a to be irradiated to the quartz cuvette tube 600, so that the ultraviolet rays of the UV radiation can be uniformly irradiated to the quartz cuvette tube 600.

As another example, a second reflective member 400b may be provided on the opposite lower sides of the quartz cuvette tube 600 as shown in FIG. 7B, and a part of the ultraviolet rays irradiated from the UV LED module 300 may be reflected by the second reflective member 400b So that the ultraviolet rays of the UV rays are uniformly irradiated onto the quartz cuvette tube 600.

As another example, the first reflective member 400a and the second reflective member 400b may be provided together to irradiate the UV light to the quartz cube tube 600 more uniformly as shown in FIG. 7C.

Meanwhile, since the lifetime of the UV light LED device 320 installed in the UV light LED module 300 is predetermined, the state of the UV light irradiated from the UV light LED module 300 is periodically determined, It is necessary to check and replace the LED module 300.

For example, the UV light LED module 300 detects UV light irradiated from the UV light LED module 300. That is, the UV light LED module 300, which is installed at the upper center of the UV light LED module, faces the quartz- The ultraviolet ray detection sensor 500 may be installed to detect the ultraviolet ray irradiated by the user,

The signal of the ultraviolet ray detection sensor 500 is transmitted to a control unit provided in the front part of the main body 100. The control unit determines the result and informs the user through a display lamp or a display unit or a speaker provided on the front panel 140 .

8A, the UV light LED module 300 has a length corresponding to the length of the quartz cuvette tube 600. The ultraviolet light sensor 500, which is integrally formed at the upper center of the UV LED module 300, It may be difficult to accurately determine the ultraviolet intensity of the UV light of the UV light module 300.

Accordingly, as shown in FIG. 5, a plurality of ultraviolet ray detection sensors 500 are provided for each section of the ultraviolet LED module 300 divided into a plurality of sections along the longitudinal direction, The ultraviolet ray can be guided to the user precisely.

As shown in FIGS. 8B, 8C, and 8D, the ultraviolet sensors 500a and 500b may be separated from the UV LED module 300 and disposed on opposite sides of the quartz cuvette 600, Or may be provided on both the upper and lower sides.

Since the life of the YBIC LED element 320 of the YBIC LED module 300 is limited depending on the use of the YBIC LED module 320, the UV light irradiated from the YBIC LED element 320 of the YBIC module 300 may be transmitted to the light- The control unit determines the time to be inspected according to the operation of the therapeutic apparatus, calculates the total cumulative irradiation time in real time, and when the cumulative irradiation time exceeds the set cumulative irradiation time, the control unit notifies the user of the cumulative irradiation time, 300 may be configured to check the replacement timing according to the failure.

In addition, even if the control unit measures the light quantity of the UV light irradiated from the UV light LED device 320 of the UV light LED module 300 and the light intensity of the UV light reaches the set light intensity, The control unit may compare the accumulated irradiation time and the measured light amount of the UV LED device 320 to determine whether the accumulated irradiation time is shorter than the predetermined irradiation time It may be configured to inform the user of the replacement time according to the failure of the UV LED module 300 when the measured cumulative irradiation time or the measured light amount does not reach the set light amount .

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. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

100: main body 110: upper frame
111: penetration part 120: horizontal plate
130: lower frame 140: front panel
150: rear panel 160: cover
200: guide bracket 210: guide groove
300: YBIC LED module 310: PCB substrate
300a: first auxiliary UCI LED module
300b: the second auxiliary UC LED module
320: YUV ELD device 400a: first reflection member
400b: second reflecting member 500: ultraviolet ray detecting sensor
600: quartz cube tube 610: grip part

Claims (16)

A horizontal frame, a lower frame installed at a lower portion of the horizontal frame, a lower frame provided at a lower portion of the horizontal frame, and a space formed at an upper portion of the horizontal plate, wherein a penetrating portion is formed at a central portion of the surface in a longitudinal direction, An upper frame, and a front panel and a rear panel installed on the front and rear surfaces of the horizontal plate; A semicylindrical portion provided at both ends of the quartz cube tube to which the blood is moved so as to be opposed to both sides in the longitudinal direction of the central portion of the upper surface of the horizontal plate, A guide bracket having guide grooves of the guide grooves; And a UV light LED module for irradiating ultraviolet rays toward the center of the side of the quartz cuvette tube which is seated on the guide bracket. The inner side of the grip part seated in the guide groove has a tapered cross-sectional structure, Wherein the grip portion is resiliently fitted in the guide groove and an optical sensor is provided on an inner circumference of the guide groove to fix the quartz cuvette in the guide groove of the guide bracket according to the operation of the photosensor when the grip portion is not correctly seated in the guide groove, And to notify the user that the grip portion of the pipe is incorrectly seated,
The YUV LED module includes a plurality of UV LED elements for irradiating ultraviolet light having a wavelength range of 250 to 280 nm,
The UV light LED module is installed on both sides of the quartz cube tube opposite to each other. The pair of UV light LED modules are arranged on the upper side of the horizontal plate so that UV light can be radiated in a diagonal direction facing the quartz cuvette tube. A second auxiliary UV LED module is provided on the upper surface of the horizontal plate so as to be irradiated with ultraviolet rays in a diagonal direction facing the quartz cuvette tube, And is disposed opposite to a hexagonal structure around the pipe,
Wherein a plurality of UBS LED elements mounted on the UBS LED module are mounted while maintaining a constant spacing along the length direction so as to correspond to the quartz cube tube, The ultraviolet ray irradiation range irradiated by the quartz cuvette tube is not separated from each other,
And an ultraviolet ray sensor for detecting ultraviolet rays irradiated from a UV LED element of the UV LED module facing the UV LED module at the upper center of the UV LED module.
The UV LED module is divided into sections along the length direction, and the UV sensor is installed in each divided section,
If the cumulative ultraviolet ray irradiation time and the amount of light irradiated by the UV light LED module of the UV light LED module are measured and compared with the predetermined cumulative light irradiation time and the light intensity can not be reached, And informs a user of the replacement of the LED module. The replacement module may be configured to inform the user through a display lamp provided on the front panel of the main body or to alert the user through the generation of a warning sound. Optical Immunotherapy System using.
delete delete The method of claim 1, wherein
Wherein the YUV LED module is installed so that the distance between the YUV LED module and the YUV LED module can be adjusted toward or away from the quartz cuvette tube, respectively. delete The method according to claim 1,
Wherein the YBIC LED device mounted on the YBIC LED module comprises one or more rows of LEDs. delete delete The method according to claim 1,
The first reflector or both sides of the upper surface of the horizontal plate are irradiated with UV light from the UV light LED module on both sides of the inner surface of the upper frame so that UV light irradiated from the UV light LED module is reflected and irradiated toward the quartz cuvette tube And a second reflection member is further provided so that ultraviolet rays of UV light are reflected and irradiated toward the quartz cuvette tube. delete delete delete delete delete delete delete

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