DE102022112351A1 - BEAM - UV - LED - ULTRAVIOLET LIGHT - SWEEPING - METHOD AND DEVICE FOR IT - Google Patents

Abstract

A condensed beam UV LED ultraviolet light sweeping method includes: activating electrical energy introduced into a circuit board to illuminate a condensed beam UV LED ultraviolet light bead and driving a motor to rotate a polygonal aluminum mirror with multiple reflective surface to rotate, wherein ultraviolet light from the UV LED is projected toward the reflective surface and reflected by the reflective surface to change the direction of light for a continuous back-and-forth home-return sweep, wherein the Light is converted from lines into sectorial shapes which are thereby connected to form a large ultraviolet light operating range. The device comprises a rotating device with a motor on which is attached a spindle with a polygonal aluminum mirror with multi-reflecting surface; a UV LED pencil beam light source assembly has a pencil beam UV LED ultraviolet light bead mounted on a printed circuit board; and a mounting base has a main body and a plurality of mounting stays.

Description

TECHNICAL FIELD OF THE INVENTION

The present invention relates to a condensed beam ultraviolet light-emitting diode (UV-LED) ultraviolet light sweeping method and apparatus therefor, which method mainly uses a condensed beam UV-LED ultraviolet light bead to deliver a high-dose radiation intensity, which is then swept to expand the usable range of high radiation dose, and further arranged in a reflection chamber for repeated reflection, which can be realized by the reflection chamber to repeatedly use the reflected ultraviolet light, and thus the radiation dose of the ultraviolet to increase light; the device is applicable to air sterilization and disinfection, or water sterilization and disinfection, or vessel surface sterilization and disinfection, or food surface freshness sweeping, plant cultivation, light therapy sweeping, and providing high radiation dose for applications of UV curing and the like.

DESCRIPTION OF THE PRIOR ART

Known ultraviolet (UV) light technology involves a mercury-containing radiation light source. Aside from its environmental hazard, this light source has a frequency band ranging from 254 nm to visible light. In this broad wavelength range, only a very small range of 250-285 nm is suitable for sterilization and only the range of 350-405 nm for light curing. A lot of energy is therefore wasted outside of these specific wavelength ranges. A UV LED is a single band and therefore uses less power. The UV LED is therefore increasingly being used as a radiation source for sterilization. However, these radiation sources are typically arranged in a fixed array or a static multi-bead distribution where the distribution is high density but the radiation dose is of poor homogeneity. The reason for this common result lies in the definition of the beam angle of an LED, where an illumination angle is an included angle between the center axis luminosity and the 50% decay luminosity (see 1 ), and there is an inhomogeneity of the 50% light emission between the light of the central axis and the light of one side. It would be difficult for the known technology to achieve light homogeneity.

The known technology does not have the ability to provide a high radiation dose for long distance and large area applications. For example, if the projection is made for a distance of 2 centimeters from a 20 × 20 mil UV LED bead with 120 degree illumination angle; the bead area or the area at the origin of the UV LED light projection is 20 × 20 mil = 0.258 mm ² , the length of the base of the isosceles triangle of the 120 degree projection at 2 centimeters is 69.788 mm, the cross-sectional area of the projection is 69.788 × 69.788 = 4870.36 mm ² , the cross-sectional area ratio between bead area and cross-sectional area at 2 cm of projection is 0.258/4870.36 = 0.000053, ie when the irradiance at the origin of the bead is 1 mw/cm ² and the irradiance is uniform distributed over the cross-sectional area at 2 cm, the irradiance per unit area is 0.000053 mw/cm ² . The intensity of the radiation and the projection distance or the cross-sectional area at that distance are inversely proportional. The projection distance and the cross-sectional area at the distance therefore have a significant impact on the irradiance. The well-known applications of UV LEDs for curing light-curing base materials are faced with the dilemma that the radiation intensity decreases as the required area of application increases. A known approach to solving the problem is to increase the light output in order to achieve the cure in the desired time. However, this often results in materials being exposed to radiant heat and scorching, with vaporized small particles contaminating the UV bead. Scorching can be prevented by increasing the clearance, but an adverse consequence is an incompletely cured tacky surface.

The well-known technology of reflection scanning is mainly used in devices for capturing and/or entering text or images. The device thus consists of two components: (1) a light source and (2) a photo sensor, as in a charge-coupled device (CCD). In such a coordinate scanning process, light vectors are required in the X-axis and Y-axis, and a Z-axis position is also required for displaying the entire outline of a text or an image; the laser is the primary light source, and the laser should be parallel to the scanned target to achieve its purpose in image processing, such as photocopier scanning or iris recognition scanning. The sweeping method in the present invention, the purpose of which is to supply only ultraviolet light energy for disinfection and sterilization, or to supply photopolymerization energy, or to support the synthesis of vitamin D, only linear vector sweeping of a light source is required, and neither X-axis, Y-axis, nor Z-axis position orientation are required for repeated original position return sweeping. Concentrated beam UV LED ultraviolet light beam surface works directly without photo sensor recording and without image capture input device. Therefore, there are angles between the position of the light source and the scanned target.

In view of the above, the inventor devotes an enormous amount of energy and spirit to the development and search for the purpose of continuous breakthrough and innovation in this field, to provide a novel measure to overcome the shortcomings of the known technology, which in addition provides a more benign Product for society, provides more efficient elimination of virus and better protection for people, and also promotes the development of UV LED industry.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a condensed beam UV-LED ultraviolet light sweeping method and apparatus, in which method a polygonal-shaped aluminum mirror having a multi-reflecting surface is rotated about the projection direction of the ultraviolet light facet for cyclic and continuous home position return position sweeping, which converts UV light from a line to a sectorial area to expand a light beam area, which expands the areas of product applications. In addition, the device uses a condensing beam UV LED bead to provide a high-dose UV light source to lengthen and widen the effective UV light beam sweeping range. In addition, the bundled beam UV LED ultraviolet light sweeping device is for sterilization and disinfection of microorganisms and viruses, oxidation of organic gases for deodorization, polymerization of organic liquids containing photoinitiators, synthesis of vitamin D for support growth of fungi and edible mushrooms and for skin phototherapy to treat skin diseases.

Ultraviolet light sterilization is the best ideal measure of sterilization, disinfection, preservation and cultivation, and is also the best way of photocuring UV resins. According to the Grotthuss-Draper law of photochemical principle, (1) a chemical reaction takes place only at an absorbable spectral wavelength. The effective absorption frequency range for the DNA and RNA of bacteria or microorganisms is around 250-285 nm, and this is the best wavelength range for sterilization and disinfection. (2) The radiation dose must be greater than the effective activation energy so that when the viruses absorb an amount greater than the lethal radiation dose, the bacteria can be killed or disinfected or sterilized by breaking the bonds. For example, for fecal coliforms, K = lethal dose 6600 µW/cm ² , and based on the formula K = I (intensity µW/cm ² ) * t (time - sec), where I is the irradiance of the irradiation, that Killing bacteria is possible in seconds if I is high enough. At a radiation intensity of less than 70 µW/cm ² , the bacteria can perform a repair function, which is called ineffective sterilization. Therefore, the wavelength range of the UV LED radiation must be appropriately wide and have a sufficiently high radiation intensity to effectively and efficiently kill bacteria and disinfect and sterilize in a safe manner without secondary contamination. Photoinitiators with a wavelength of 350 - 405 nm (light absorbing range) are often added to UV resins, and rapid curing can be achieved by supplying UV radiation of an appropriate wavelength. In addition, 280 - 350 nm can be used for phototherapy and plant cultivation, and helps in the synthesis of vitamin D.

In order to achieve the above object, the present invention provides a condensed beam UV-LED-ultraviolet light sweeping method, the sweeping steps of which are as follows: activation of electric power for input to a circuit board to emit a UV-LED-ultraviolet light - Illuminate Bead and also drive a motor to cause a polygonal aluminum mirror with multiple reflective surface mounted on a motor spindle to rotate; Projecting a UV light beam towards the aluminum mirror with reflective surface when rotating, so that the ultraviolet light is reflected by the aluminum mirror when rotating to change the direction of the light for continuous back and forth home position return sweeping and to convert the UV light from lines to sectorial shapes, the multiple sectorial shapes being connected to form a large ultraviolet forming a light beam area, which is referred to as a pencil beam UV LED ultraviolet light sweeping method.

In order to achieve the above objects, the present invention provides a condensed beam UV-LED ultraviolet light sweeping device which comprises at least a rotating device, a UV-LED condensed beam light source assembly and a mounting base, the rotating device comprising a motor and a polygonal aluminum mirror with multi-reflective surface; the aluminum multi-reflective surface polygonal mirror is mounted on a spindle of the motor, the spindle and aluminum multi-reflective surface polygonal mirror being mounted in a hole-to-hole mount or additionally fitted with a universal joint to provide a centerline offset between the to eliminate both; further, the UV-LED pencil beam light source assembly comprises at least a pencil-beam UV-LED ultraviolet light bead and a circuit board, wherein the pencil-beam UV-LED ultraviolet light bead is mounted on the circuit board; in addition, the mounting base includes a main body and a plurality of mounting stays, the main body of the mounting base supporting the components, and the main body and the mounting stays are integrally formed as a unit or are separate parts, with one of the mounting stays being provided with a power supply port. The mounting base may be made of an organic material coated with a metallic material, an inorganic material, or a metallic material.

The concentrated beam UV-LED ultraviolet light sweeping device according to the present invention further comprises a reflection chamber, wherein the reflection chamber is a circular shape, a square shape, or an irregular shape with a highly reflective layer made of aluminum. The swept and projected ultraviolet light projected from a UV LED moves while reflecting off the high-reflectivity aluminum of the reflection chamber to return in one direction toward the mounting base, undergoing multiple continuous deflection and reflection, until the radiant light runs out, with the reflection chamber helping to improve the reuse of the radiant light and shorten the sterilization time. A disadvantage of sterilization with ultraviolet light is that if the light travels in a straight line, bacteria that are behind dust on the side that is not exposed to the light can escape. By repeatedly changing the direction of the UV light, the escape of the bacteria can be avoided, and this is the unique effect provided by the present invention.

The bundled beam UV LED ultraviolet light sweeping device according to the present invention further includes a side-opened reflection chamber, and the side-opened reflection chamber includes a side opening to allow the radiation light to pass through the opening to the outside for surface sterilization of medical devices and is projected for keeping food fresh and preserving, wherein the radiation width or radiation area is determined by an angular size and a length of the side opening of the side-opened reflection chamber. ( 8th )

In the condensed beam UV-LED ultraviolet light sweeping device according to the present invention, the condensed beam UV-LED ultraviolet light bead is a conventional 250-405 nm UV-LED primary encapsulation ultraviolet light bead which is coated with a secondary encapsulation of a 1.2mm-20mm height hollow metal tube is added, and the greater the height, the smaller the light emission angle, and the more concentrated the light intensity, and the length can be changed according to requirements, and the UV LED -250-405nm Light Bead is not a laser beam and depends on the internal reflection of a hollow metal internal mirror surface to change the direction of movement of light radiation and allow overlapping of light for homogeneity, and the opening size of the hollow metal tube limits the light shape and makes the light uniform and concentrated to be called "concentrated beam". The inventor of the present invention recognizes that the principle of the Maddox rod can be applied here to control the direction of UV light reflection and the hollow metal tube can be further processed to direct in a direction perpendicular to a surface of the radiation light from a semiconductor to be emitted, a continuous internally corrugated columnar triangular configuration reflecting mirror, as in the sectional view 3e , or a continuous internally corrugated columnar reflecting mirror of rectangular configuration, as in the sectional view 3f , or a continuous internally corrugated arcuate configuration aluminum reflecting mirror as in the sectional view 3d shown, the radiation light is projected outward in a direction perpendicular to a semiconductor surface, and the reflection light forms a meridian surface focusing line perpendicular to the continuous columnar reflection mirror to form a condensed beam UV LED ultraviolet light bead, which forms a condensed beam provides straight extending in a direction parallel to the semiconductor light source, and a sol cher bundle beam is further subject to the constraint of the secondary optics by a hollow metal tube to change the angle and propagation direction of the light to form a concentration of the light for excellent light homogeneity, and the propagation direction is parallel to the straight extension direction of the hollow metal tube, where the angle is small to be suitable for long-distance sweeping, and also to provide a high ultraviolet light radiation dose beam, and secondary encapsulation can be realized with the inner rectangular and outer rectangular or inner circular and outer circular or inner circular and outer rectangular hollow metal tube and the hollow metal can be one of aluminum, copper, nickel, tin or aluminum powder coated metal and is fixed on the circuit board to serve as an ultraviolet light - radiation light source assembly used in the condensed beam UV LED Ultravi olett light sweeping method according to the present invention is used.

In the bundled beam UV-LED ultraviolet light sweeping device according to the present invention, the rotating device is a device for driving the polygonal aluminum mirror with multi-reflective surface, and the polygonal aluminum mirror with multi-reflective surface requires at least three or more than three aluminum reflective surface mirrors , and the motor for the rotational force of the rotary device is AC motor, DC motor, brushless motor or servo motor, and the polygonal aluminum mirror with multi-reflective surface fits over and is fixed to the spindle of the motor, and the polygonal surface forms an included angle θ with respect to a side face of the reflective surface, see 4 , and the two together form the turning device.

In the condensed beam UV-LED ultraviolet light sweeping device according to the present invention, the mounting base includes a main body and a plurality of mounting stays, and the main body of the mounting base fixes the rotary device and the UV-LED condensed beam light source assembly, and the main body and the fixing struts may be integrally formed as a unit or are separate parts, and one of the fixing struts is provided with an electric power supply port, and the fixing struts are mountable within the aluminum reflection chamber. In addition, the material of the mounting base may be an inorganic material, an organic material, or a metallic material. The main body of the mounting base is provided with mounting bolt holes for the motor and the circuit board of the rotary device, and the mounting base includes a plurality of mounting stays. A substrate of the circuit board may be a PCB (RF-4 Organic Material), an MCPCB (Metal Core PCB), or a ceramic PCB.

In the condensed-beam UV-LED ultraviolet light sweeping device according to the present invention, when the condensed-beam UV-LED ultraviolet light bead has a wavelength in the range of 250-285 nm, an effect of sterilization and sterilization is exhibited Disinfection, and according to the formula of the technical standards for sterilization and disinfection, the bactericidal radiation dose is K=I (radiation intensity µW/cm ² ) * t (irradiation time - sec), and the more intense the radiation dose, the shorter the time, where the two are inversely proportional to each other. The bundled beam UV LED ultraviolet light bead provides ultraviolet light with a high radiation dose, which has the characteristics of processing a large number of bacteria with sterilization and disinfection in a short time, and the bundled beam UV LED light intensity Ultraviolet light beads is high to reduce decay for the long-distance projection of the ultraviolet light (see Table 1, comparison table of the radiation intensity of the illumination angle VS distance from the irradiation target), is for a long-distance high radiation dose back and forth home position return -Sweeping method suitable, it expands the processing radiation light operating range, and also makes the radiation dose distribution uniform; it has the advantage of including non-dead zones in the sweep operating range. Table 1 distance from the lighting target 0cm 1 cm 2 cm 3 cm 4 cm Radiant intensity (mW/cm ² ) for a 3 degree illumination angle 469.3 444.89 425.66 412.05 401.76 Area unit - irradiance in percent 100% 94.8% 90.7% 87.8% 85.6% Radiant intensity (mW/cm ² ) for an illumination angle of 120 degrees 469.3 33.12 4.14 1.68 0.027 Area unit - irradiance in percent 100% 7.1% 0.9% 0.04% 0.006%

In the condensed beam UV-LED ultraviolet light sweeping device according to the present invention, when the condensed beam UV-LED ultraviolet light bead of the present invention has a wavelength of 350-405 nm, it is applicable to photopolymerization and curing , and is based on the principle of Einstein's law of photochemical equivalence; The Condensed Beam UV LED Ultraviolet Light Bead provides high radiation dose UV light back and forth equal displacement sweeping, eliminates the need to reduce the distance to the objects being cured or correspondingly require less UV LED power , so that the radiant heat is small, thereby preventing the UV resin from being easily scorched, and the low-molecular UV resin layer is not easily vaporized to contaminate the bead, and the influence of heat is reduced , to prevent burning and odor, and an advantage is smoothness and low radiant heat of the product.

In the bundled beam UV-LED ultraviolet light sweeping device according to the present invention, the polygonal surface of the aluminum polygonal mirror having multiple reflecting surfaces forms a θ-corner with respect to the side surface of each of the reflecting surfaces, and when the θ-corner of the reflective surfaces are all identical θ-Wmkel for each of the reflective surfaces, the at least one bundle beam - UV - LED - Ultraviolet - light - bead on the circuit board projects the ultraviolet light thus emitted towards the reflective surfaces of the polygonal aluminum mirror with multiple - reflective surface , and the light beam is reflected by the reflective surface to form an evenly distributed planar UV beam area, as in 5a .

In the bundled beam UV-LED ultraviolet light sweeping device according to the present invention, the polygonal surface is connected to a side surface of the reflecting surface of the polygonal aluminum mirror with multi-reflecting surface to form an angle θ different for each of the surfaces is, as in 4a , 4b and 4c shown, and at least one condensing beam UV LED ultraviolet light bead on the circuit board projects an emitted light beam toward the side faces of the reflecting surfaces of the aluminum multi-reflecting surface polygonal mirror, and each light beam is reflected as reflection light with a different angle θ for each of the reflecting surfaces, and a Z-axis height is increased, and the reflection light beam forms a uniformly distributed 3D UV light beam area, as in 5b shown.

1. (1) Bereitstellung einer hohen UV-Strahlungsdosis zur Abtötung von Bakterien in Sekunden.
2. (2) Ermöglichung von Langstrecken-Projektion der Strahlungsdosis (Tabelle 1).
3. (3) Ermöglichung eines großflächigen Einheits-Sweeping und Projektion einer hohen homogenen Strahlungsdosis.
4. (4) Verbesserung der flächenbezogenen Strahlungsdosis von ultraviolettem Licht und Reduzierung der Strahlungswärme.
5. (5) Ermöglichung von Nicht-Todes-Zonen-Hochstrahlungsdosis mit Links-Rechts-Vor- und-Zurück-Verschiebungs-Sweeping wie in 5a gezeigt.
6. (6) Ermöglichung eines Aufwärts-Abwärts-Links-Rechts-Dreidimensionalen-Rückwärts-und-Vorwärts-3D-Verschiebungs-Sweeping wie in 5b gezeigt, was einen breiten Anwendungsbereich ermöglicht.

The bundled beam UV LED ultraviolet light sweeping method and apparatus according to the present invention offers the following advantages:

1. (1) Providing a high dose of UV radiation to kill bacteria in seconds.
2. (2) Enable long-distance projection of radiation dose (Table 1).
3. (3) Enable large area unit sweep and project high homogeneous radiation dose.
4. (4) Improving the areal radiation dose of ultraviolet light and reducing radiant heat.
5. (5) Enabling non-death zone high radiation dose with left-right fore and aft shift sweeping as in 5a shown.
6. (6) Enable up-down-left-right three-dimensional back-and-forth 3D displacement sweeping as in 5b shown, which allows a wide range of applications.

character list

• 1 Fig. 12 is a graph showing the relationship between the luminance on a central axis and the 50% decay luminance.
• 2 14 is an exploded view showing the structure of a concentrated beam UV-LED ultraviolet light sweeping device according to Embodiment I of the present invention.
• 3a Fig. 12 is a schematic view showing an inner-circle and outer-circle metal tube with secondary encapsulation according to the present invention.
• 3b Fig. 12 is a schematic view showing an internally rectangular and externally rectangular hollow metal pipe with secondary encapsulation according to the present invention.
• 3c Fig. 12 is a schematic view showing an inside-circular and outside-rectangular hollow metal tube according to the present invention.
• 3d Fig. 12 is a schematic view showing a secondary encapsulation hollow metal tube according to the present invention having an inner mirror surface formed with a continuously corrugated columnar reflecting mirror of arc configuration.
• 3e Fig. 12 is a schematic view showing a secondary encapsulated metal hollow tube according to the present invention having an inner mirror surface formed with a continuously corrugated columnar reflection mirror of triangular configuration.
• 3f Fig. 12 is a schematic view showing a secondary encapsulated metal hollow tube according to the present invention, having an inner mirror surface formed with a continuously corrugated columnar reflecting mirror of rectangular configuration.
• 4a - 4c 12 are schematic views showing various included angles θ between a polygonal surface and a side face of a reflecting surface of an aluminum polygonal mirror having multiple reflecting surfaces according to the present invention.
• 5a 12 is a schematic view showing light emission under the condition that the included angles θ between a polygonal surface and the side face of the reflecting surfaces of an aluminum polygonal mirror having multiple reflecting surfaces are identical for each surface according to the present invention.
• 5b 12 is a schematic view showing light emission under the condition that included angles θ between a polygonal surface and side faces of reflecting surfaces of an aluminum polygonal mirror having multiple reflecting surfaces are different for each surface according to the present invention.
• 6a 12 is a side plan view showing a reflection chamber according to the present invention.
• 6b 12 is a plan view showing a reflection chamber according to the present invention.
• 6c Fig. 12 is a schematic view showing a closed-loop improved condensed beam UV-LED ultraviolet light sweeping apparatus according to Embodiment II of the present invention.
• 7 12 is a schematic view showing a collimated beam UV-LED ultraviolet light sweeping apparatus according to Embodiment III of the present invention.
• 8th 12 is a schematic view showing a collimated beam UV-LED ultraviolet light sweeping apparatus according to Embodiment IV of the present invention.
• 9a 12 is a schematic view showing a concentrated beam UV-LED ultraviolet light sweeping apparatus according to Embodiment V of the present invention.
• 9b Figure 12 is a schematic view of a polygonal aluminum reflective surface mirror having an irregularly shaped elongated columnar configuration in accordance with the present invention.
• 10 12 is a schematic view showing a collimated beam UV-LED ultraviolet light sweeping apparatus according to Embodiment VI of the present invention.
• 11 12 is a schematic view showing a concentrated beam UV-LED ultraviolet light sweeping device according to Embodiment VII of the present invention.
• 12 Figure 12 is a flow chart illustrating a pencil beam UV-LED ultraviolet light sweeping method in accordance with the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The present invention provides a condensed beam UV LED ultraviolet light sweeping method and apparatus. In order that those who are familiar with the general knowledge in related fields can fully understand the object, features and advantages of the present invention, suitable embodiments are described below with reference to the accompanying drawings and a detailed description of the technical content of the present invention shown.

Embodiment I: A concentrated beam UV-LED ultraviolet light sweeping device

Referring to 2 14 is an exploded view showing the structure of a collimated beam UV-LED ultraviolet light sweeping device according to Embodiment I of the present invention.

As in 2 As shown, the condensed beam UV-LED ultraviolet light sweeping device 1 includes: a rotating device 10, a UV-LED condensed beam light source assembly 20, and a mounting base 30. The rotating device 10 includes a motor 11 and a polygonal aluminum mirror with multi-reflective surface 12 which fits onto a spindle 111 of motor 11. Each side of the aluminum polygonal mirror with multi-reflective surface 12 forms a reflective surface 121. On top of the aluminum polygonal mirror with multi-reflective surface 12, a polygonal surface 122 is formed. The polygonal surface 122 forms an included angle θ with respect to the multi-reflective surfaces 121, as shown in FIG 4a shown. Mounting of the aluminum polygonal mirror with multi-reflective surface 12 to the motor spindle can be by direct mounting or indirect mounting using an intermediate universal bearing to eliminate the misalignment between the spindle and the aluminum polygonal mirror with multi-reflective surface 12. Next, the UV-LED concentrated beam light source device 20 includes a circuit board 22 and at least one concentrated beam UV-LED ultraviolet light bead 3 mounted on the circuit board 22. Further, the mounting base 30 includes a main body 31 and a plurality of mounting stays 32. The Main body 31 provides a platform for supporting elements, such as mounting the motor 11 and circuit board 22, in which motor seat bolt holes 112 for mounting the motor 11 on the main body 31 and circuit board bolt holes 113 for mounting the circuit board 22 on the main body 31 are provided. One of the fixing stays 32 is provided with a power supply opening 321 among the fixing stays 32 . The mounting base 30 is made of either an organic material coated with metallic aluminum, an inorganic material, or a metallic material. The power supply port 321 is connected to the at least one condensed beam UV LED ultraviolet light bead 3 and the motor 11 . When electric current is activated, the electric current is fed into the circuit board 22, and the motor 11, and at least one condensed beam UV LED ultraviolet light bead 3 is activated at the same time to drive the polygonal aluminum mirror with multi-reflective surface 12, so that it rotates, and the condensing beam UV LED ultraviolet light bead 3 on the circuit board 22 emits and projects a light beam toward the reflecting surface 121 of the polygonal aluminum mirror with multi-reflecting surface 12, and a reflection light beam is projected toward a working area, to form a homogeneously distributed sectorial-shaped light beam area, and a plurality of sectorial areas are connected to form a circular, large-area light beam area. The polygonal aluminum mirror with multiple reflective surface 12 is formed by plastic injection molding and then coated with metallic aluminum by vacuum electroplating, or fabricated directly by machining or processing aluminum, nickel, copper, or zinc. The aluminum polygonal mirror with multi-reflection surface 12 is provided with a mounting hole 123 at its center for mounting and fixing on the spindle 111 of the motor 11 . The motor 11 can be either an AC motor, a DC motor, a brushless motor or a stepping motor.

Referring to the 3a - 3f , 3a Fig. 12 is a schematic view showing an inner-circle and outer-circle metal hollow pipe according to the present invention; 3b Fig. 12 is a schematic view showing an internally rectangular and externally rectangular hollow metal pipe according to the present invention; 3c Fig. 12 is a schematic view showing a circular inside and outside rectangular hollow metal tube according to the present invention; 3d Fig. 12 is a schematic view showing a hollow metal pipe according to the present invention, having an inner mirror surface formed with a continuously corrugated columnar reflecting mirror of arc configuration; 3e Fig. 12 is a schematic view showing a hollow metal pipe according to the present invention, having an inner mirror surface formed with a continuously corrugated columnar reflection mirror of triangular configuration; and 3f 12 is a schematic view showing a hollow metal pipe according to the present invention, having an inner mirror surface formed with a continuously corrugated columnar reflection mirror of rectangular configuration. This secondary encapsulation uses either the inner rectangular and outer rectangular shaped hollow metal tube, or the inner circular and outer circular shaped hollow metal tube, or the inner circular and outer rectangular shaped hollow metal tube, and the material of the hollow metal tube can be either aluminum, copper, nickel, tin, or a metal coated with aluminum powder.

As in 3a - 3f As shown, the condensed beam UV LED ultraviolet light bead 3 is such that secondary encapsulation is applied to encapsulate and mount a hollow metal tube 211 on a lead frame mount 212 by application of methyl silicone, on which a conventional ultraviolet light bead 21 The UV LED is mounted by a primary encapsulation, and radiation light is reflected back and forth by a reflective aluminum mirror surface 2111 inside the hollow metal tube 211 to form a homogeneous concentric light beam for projection outward with a small angle of divergence to achieve a high project radiation dose. Based on the principle of the applied Maddox rod, the hollow metal tube 211 is formed as a surface perpendicular to the radiation light emanating from the semiconductors, a non-spherical columnar reflective mirror surface 2111, which is a continuous internally corrugated columnar shape with arc configuration 2112, a continuous internally corrugated columnar shape with triangle configuration 2113, a continuous internally corrugated columnar shape with rectangular configuration 2114, and the radiation light is perpendicular to the columnar surface to project outward to achieve meridian direct light incidence, which is a straight bundle beam UV LED -Light forms in a direction perpendicular to a semiconductor surface. The straight light can be further projected with the beam being further converged to serve as a radiation light source of the bundled beam UV-LED ultraviolet light bead 3 for a sweeping process.

Referring to the 4a - 5b , 4a - 4c 12 show various included angles θ between the polygonal surface 122 and a side surface of the reflecting surface of a multi-reflecting surface aluminum polygonal mirror 121 according to the present invention; and 5a 12 is a schematic view showing that the included angles θ between the polygonal surface 122 and the side faces of the reflecting surfaces of the aluminum multi-reflecting surface polygonal mirror 121 according to the present invention are identical for each surface, and 5b 12 is a schematic view showing that the included angles θ between a polygonal surface 122 and the side faces of the reflecting surfaces of the aluminum multi-reflecting surface polygonal mirror 121 according to the present invention are different for each surface.

As in 2 shown, the aluminum polygonal mirror with multiple reflective surfaces 12 includes three or more than three reflective surfaces 121. The included angle θ between the reflective surfaces 121 and the polygonal surface 122 of the aluminum polygonal mirror with multiple reflective surfaces 12 can be identical or different for each of these surfaces be. If the included angle θ is identical for each of these surfaces, as in 5a shown, the reflected ultraviolet light changes from a line to a sectorial shape to thereby expand an operation space; when the included angle θ is different for each of these surfaces, a thickness in the Z-axis direction is increased in addition to the divergent surfaces formed in the Y-axis and the X-axis, as shown in FIG 5b shown, the operating space of the ultraviolet light increases three-dimensionally to provide an increased design space for a greatly expanded application of products.

Embodiment II: a closed-loop enhanced collimated beam UV-LED ultraviolet light sweeping device

Referring to the 6a - 6c , 6a Fig. 12 is a side plan view showing a closed reflection chamber according to the present invention; 6b Fig. 12 is a plan view showing the closed reflection chamber according to the present invention; and 6c Fig. 12 is a schematic view showing a closed-loop improved condensed beam UV-LED ultraviolet light sweeping apparatus according to Embodiment II of the present invention.

As in 6a - 6c shown, the closed improved condensed beam UV LED ultraviolet light sweeping device 2 comprises a closed reflection chamber 40. The closed reflection chamber 40 has, as already mentioned, openings 401 for mounting the mounting struts 32, and the power supply opening 321 connects at least one condensing beam -UV-LED-Ultraviolet Light-Bead 3 and the turning device 10 and is fastened with screws. The inner wall of the closed reflection chamber 40 consists of a highly reflective aluminum layer. When the electrical energy source is activated, the electrical energy is fed into the circuit board 22, and the motor 11, and at least one (or more) UV - LED - ultraviolet light - bead (s) 3 are activated simultaneously to the polygonal aluminum mirror with multiple reflective surface 12 to drive it to rotate, and at least one (or more) bundled UV LED ultraviolet light bead (s) 3 on the circuit board 22 generate a light beam that is directed towards the reflective surface 121 of the polygonal aluminum mirror with more multi-reflecting surface 12, and a light beam of reflection is projected toward the closed reflection chamber 40 to be reflected by an aluminum mirror of the closed reflection chamber 40. The inner wall of the closed reflection chamber 40 is a columnar non-spherical pattern, and the columnar non-spherical pattern is perpendicular to the incident light. The columnar non-spherical pattern may be arc configuration, triangular configuration, or rectangular configuration. The behavior of light reflection of light projected onto a columnar non-spherical reflecting surface, which conforms to the principles of the Maddox Rod, as discovered by the inventor of the present invention, is applied here. When hitting the columnar non-spherical pattern, the reflection light forms a secondary reflection light whose meridian direction is in a direction perpendicular to the columnar non-spherical pattern, which in turn causes the radiation light to overlap within the operating range until it dies down and disappears , thereby forming a high-dose radiation area with homogeneous distribution, in which the reflection light of ultraviolet light strengthens the radiation inside, while reducing the leakage of radiation from the reflection chamber to the outside, thereby reducing secondary contamination and user safety protection to ensure.

Embodiment III Application of embodiment II, a closed-loop enhanced bundled-beam UV-LED ultraviolet light sweeping device, in central air-conditioning systems

Referring to 7 , 7 12 is a schematic view of Embodiment III of the present invention, showing the application of a closed-loop improved bundled beam UV-LED ultraviolet light sweeping device according to Embodiment II of the present invention in central air conditioning.

As in 7 As shown, the closed enhanced collimated beam UV LED ultraviolet light sweeping device 6c is mounted between a ventilation duct 41 and an air outlet 42 of an air conditioner such that when the circulating air moves (in a direction indicated by an arrow 411), to enter, in a passive manner, the closed enhanced condensed beam UV-LED ultraviolet light sweeping device 6c, the motor 11 is activated to rotate, the condensed beam UV-LED ultraviolet light bead 3 is turned on at the same time, which allows sweeping with ultraviolet light of the UV LED with a wavelength of 250 - 285nm, and the high dose of radiation is enough to quickly disinfect and sterilize viruses and deodorize organic gases, and by means of the air circulation associated with the air conditioning system is realized, the disinfection and sterilization of viruses and purification of the air with the support of the removal of vo n odors are obtained from it, for indoor applications such as a central air-conditioning device, an air conditioner, a ship, an airplane, a car, a subway, a train.

Embodiment IV: a side-opened extended bundled beam UV-LED ultraviolet light sweeping device

Referring to 8th , 8th 12 is a schematic view showing a collimated beam UV-LED ultraviolet light sweeping apparatus according to Embodiment IV of the present invention.

As in 8th shown, the concentrated beam UV-LED ultraviolet light sweeping device of the present invention can be shown in FIG 2 further comprising a side-opened reflection chamber 40-1 opened at one side or a periphery to form a partial opening, wherein the rotary device is arranged inside the side-opened reflection chamber 40-1 and the polygonal aluminum mirror with multi-reflecting surface 12 having the Spindle 111 of the motor 11 is connected to be driven by the motor 11 to rotate, with one of the mounting stays 32 being a power supply port 321 for connection to the circuit board 22. Embodiment IV can be used for surface sterilization for medical devices, food preserving and preserving, with a box shown in phantom lines indicating a possible surface sterilization container in which a side-opened improved bundled beam UV-LED-ultraviolet light sweeping device according to Embodiment IV of the present invention is installed.

Embodiment V: A side-opened intensified bundled beam UV-LED ultraviolet light sweeping device according to Embodiment IV of the present invention

Referring to 9a , 9a 12 is a schematic view showing a concentrated beam UV-LED ultraviolet light sweeping apparatus according to Embodiment V of the present invention; and 9b Fig. 12 is a schematic view showing an elongated irregularly shaped polygonal columnar aluminum reflective surface mirror according to the present invention.

As in 9a and 9b shown, the concentrated beam UV-LED ultraviolet light sweeping device of the present invention in FIG 2 includes the side-open reflection chamber 40-1, with the rotary device 10 being disposed within the side-open reflection chamber 40-1. The polygonal aluminum multi-reflective surface mirror 12 is a multi-angle multi-sided columnar aluminum reflective surface mirror or a multi-angle irregularly shaped multi-sided columnar aluminum reflective surface mirror 9b , and the polygonal aluminum mirror with multiple reflecting surface 12 is connected to the spindle 111 of the motor 11 to be driven by the motor 11 and rotate. Further, the elongate circuit board 22 is similarly arranged inside the laterally opened reflection chamber 40-1 at a position adjacent to the opening. A plurality of UV LED ultraviolet light beads 3 are mounted on circuit board 22 . Further, the mounting base 30 fixes the motor 11 and the polygonal aluminum mirror with multi-reflective surface 12 of the rotary device, and the multiple mounting stays 32 are fixed to the side-opened reflection chamber 40-1, one of the mounting stays 32 having a power supply hole 321 for connection with the circuit board 22 is. The current embodiment V uses a bundled beam UV LED ultraviolet light bead of a wavelength of 350 - 405 nm. By means of the aluminum polygonal mirror with multi-reflecting surface 12, radiation light is projected through the opening to the outside, and the radiation light beam projected to the outside is perpendicular to a surface of the UV resin that needs to be polymerized and cured, and moves back and forth, up and down, left and right, for sweeping, around a high-dose radiation light beam area to carry out a curing process for the polymerization and curing of To form UV resin over a large area, the photoinitiators contained in the UV resin are exposed to the high energy of radiation to rapidly polymerize and cure without being overheated and scorched. The bundled beam UV-LED ultraviolet light sweeping method and apparatus according to the present invention is such that the radiation light is projected in a direction onto the opening to be perpendicular to the surface of the UV resin and activation of electric power to perform left and right reciprocation for sweeping to perform UV resin curing and curing operation in a large area to move UV resin in liquid state quickly and high Obtaining radiant energy for rapid polymerization and curing, without overheating and consequent depletion, while the radiant energy is low, making it difficult to vaporize molecules, and generating relatively little fouling on the bead, resulting in an increase in bead life, which is good for applications requiring photocuring.

Embodiment VI: Improved Condensed Beam UV LED Ultraviolet Light Sweeping Apparatus with Air Suction or Air Supply Power

Referring to 10 , 10 12 is a schematic view showing a collimated beam UV-LED ultraviolet light sweeping apparatus according to Embodiment VI of the present invention.

As in 10 Shown is the reflective chamber 40 of the closed improved collimated beam UV-LED ultraviolet light sweeping apparatus 2 of FIG 6c connected to an air suction/blowing machine 43. The reflection chamber 40 contains a columnar continuous stripe pattern inside, which prevents the radiation from escaping. When the radiation light falls on the non-spherical columnar reflection mirror, the reflection light forms a meridian light in a direction perpendicular to the columnar shape, making it difficult to escape, thereby reducing secondary pollution while the air in the center is driven by the air intake/blowing machine to turn to flow through the sweeping device, with the direction of airflow indicated by an arrow 411, to actively sterilize and disinfect the air, making it particularly suitable for large open spaces, such as a hotel, an exhibition center, a school , a department store and a shopping mall as a mid-range active sterilization and disinfection device.

Embodiment VII: Improved Condensed Beam UV LED Ultraviolet Light Sweeping Device for Water Disinfection

Referring to 11 , 11 12 is a schematic view showing a concentrated beam UV-LED ultraviolet light sweeping device according to Embodiment VII of the present invention.

As in 11 shown, the condensed beam UV-LED ultraviolet light sweeping apparatus according to the present invention may further comprise a quartz glass sleeve 44 that hermetically accommodates the rotary device 10 and the UV-LED condensed beam light source assembly 20 on the mounting base of the main body 31, wherein the Quartz glass sleeve 44 for water resistance and water protection of the concentrated beam UV-LED ultraviolet light sweeping device 1 and also serves as an observation window through which light passes. The hermetically sealed, waterproof, bundled beam UV LED ultraviolet light sweeping device from 1 can be used for disinfection in water, for example. A high dose of radiation is enough to quickly eliminate bacteria, to carry out disinfection and sterilization for still or running water, for disinfection of drinking water, in swimming pools, aquafarming facilities, etc. for disinfection and sterilization.

Embodiment VIII: A flow chart showing the sweeping method of a pencil beam UV-LED ultraviolet light sweeping apparatus

Referring to 12 14 is a flow chart showing the sweeping method of a concentrated beam UV-LED ultraviolet light sweeping apparatus according to Embodiment VIII of the present invention.

As in 12 1, the scanning method of a narrow beam UV-LED ultraviolet light device includes Step 1 (12-1): providing a printed circuit board (PCB) 22 with an electric power supply inserted through a power supply opening 321 and activating the electric power, to illuminate at least one condensed beam UV LED ultraviolet light bead 3 on circuit board 22, and also driving a rotating device 10 to rotate a polygonal aluminum mirror with multi-reflective surface 12 on a spindle 111 of a motor 11; Step 2 (12-2): ultraviolet light emitted from at least one condensed beam UV-LED ultraviolet light bead 3 is projected onto a reflecting surface 121 of the polygonal aluminum mirror with multi-reflecting surface 12, knowing from the reflection principle that if an angle of incidence keeps changing during rotation; Step 3 (12-3): an angle of the reflection light properly changes direction, the successive back and forth home position return for position light emission enables reflection light to form a sectorial shaped radiation light surface by the present invention, from which the surface with a distance therefrom is enlarged outwardly, connecting a plurality of such sectorial-shaped radiation light areas results in the enlarged working range of ultraviolet light radiation.

The above descriptions of the various embodiments of the present invention have been presented for purposes of illustration, and are not intended to be exhaustive or limited to the embodiments shown. Many modifications and variations within the scope and spirit of the described embodiments of the present invention will be apparent to those of ordinary skill in the art. Therefore, these modifications and/or variations are permissible within the scope of the present invention.

Claims (18)

A collimated beam ultraviolet light emitting diode (UV-LED) ultraviolet light sweeping method, the method comprising the steps of: Step 1: Providing electric current fed into a printed circuit board (PCB) and activating the electric current to illuminate a collimated beam UV LED ultraviolet light bead and simultaneously driving a rotary device to rotate a polygonal aluminum mirror with multiple rotating a reflective surface on a motor spindle; Step 2: projecting a condensed beam of ultraviolet light onto the aluminum multi-reflective surface rotating polygonal mirror, the ultraviolet light being reflected by the aluminum multi-reflective surface rotating polygonal mirror to start sweeping; Step 3: The reflected ultraviolet light changes direction due to the continuous back and forth home position return sweeping, and converts the UV light projection from a line to a sectorial area, the sectorial shapes can be further connected to produce a larger ultraviolet light -To form radiation area. A concentrated beam UV-LED ultraviolet light sweeping apparatus, comprising at least: a rotary device, the rotary device providing a motor, a spindle of the motor being mounted on a polygonal aluminum mirror having a multi-reflective surface; a UV LED bundle delbeam light source kit, wherein the UV LED pencil beam light source assembly comprises at least one pencil beam UV LED ultraviolet light bead and a circuit board, wherein the pencil beam UV LED ultraviolet light bead is mounted on the circuit board; a mounting base, the mounting base including a main body serving as a platform for supporting components, and a plurality of mounting stays. Concentrated Beam UV LED Ultraviolet Light Sweeping Device claim 2 , further comprising a reflection chamber, wherein the mounting base is fixed inside the reflection chamberö an inner wall of the reflection chamber is a highly reflective aluminum sheet, the inner wall of the reflection chamber includes a columnar non-spherical pattern, the columnar non-spherical pattern is in the direction perpendicular to the incident light and the columnar non-spherical pattern may be either an arc configuration, a triangular configuration, or a rectangular configuration. Concentrated Beam UV LED Ultraviolet Light Sweeping Device claim 2 , further comprising a quartz glass sleeve, wherein the quartz glass sleeve is fixed on the main body of the mounting base by silicone. Concentrated Beam UV LED Ultraviolet Light Sweeping Device claim 2 wherein the condensed beam UV LED ultraviolet light bead includes an ultraviolet light bead with a 250 - 405 nm UV LED primary encapsulation to which is added a hollow metal tube with a secondary encapsulation bonded with silicone; wherein the height of the hollow metal tube is in the range of 1.2mm to 20mm. Concentrated Beam UV LED Ultraviolet Light Sweeping Device claim 5 , wherein the secondary encapsulation uses a hollow metal tube with an inner rectangular and outer rectangular configuration or an inner circular and outer circular configuration or an inner circular and outer rectangular configuration, and the material of the hollow metal tube can be one of aluminum, copper, nickel, tin or be a metal coated with aluminum powder. Concentrated Beam UV LED Ultraviolet Light Sweeping Device claim 6 , wherein the hollow metal tube of the secondary enclosure has an inner surface which is either a continuous internally corrugated arc configuration reflecting mirror, or a continuous internally corrugated triangular configuration reflecting mirror, or a continuous internally corrugated rectangular configuration reflecting mirror, the direction of the continuous corrugations being perpendicular to the direction of light projection , and the material of the hollow metal tube can be either aluminum, copper, nickel, tin or metal coated with aluminum powder. Concentrated Beam UV LED Ultraviolet Light Sweeping Device claim 2 , wherein the aluminum multi-reflective surface polygonal mirror comprises three or more reflective surfaces, wherein the aluminum multi-reflective surface polygonal mirror is formed by plastic injection molding and then coating with metallic aluminum by vacuum electroplating, or is formed by direct machining or processing of metallic aluminum, and the polygonal surface forms an included θ angle with respect to each of the reflective surfaces, the θ angle being either a θ angle common to each of the reflective surfaces or a θ angle common to each of the reflective surfaces is different. Concentrated Beam UV LED Ultraviolet Light Sweeping Device claim 2 , where the motor is either an AC motor, a DC motor, a brushless motor or a stepper motor. Concentrated Beam UV LED Ultraviolet Light Sweeping Device claim 2 wherein the circuit board of the UV-LED pencil beam light source assembly is either a polymer circuit board, a metal circuit board or a ceramic circuit board. Concentrated Beam UV LED Ultraviolet Light Sweeping Device claim 2 , wherein the main body and the mounting stays can be formed by a unitary body or formed by separate parts, and one of the mounting stays is provided with a power supply hole, and the material of the mounting base is either an inorganic material coated with metallic aluminum, an inorganic Material or a metallic material can be. Concentrated Beam UV LED Ultraviolet Light Sweeping Device claim 3 further comprising an air outlet and a ventilation duct, wherein the air outlet and the ventilation duct are arranged on two sides of the reflection chamber, respectively. Concentrated Beam UV LED Ultraviolet Light Sweeping Device claim 3 further comprising an air suction/blowing device, wherein the air suction/blowing device is fixed to a side of the reflection chamber. Concentrated Beam UV LED Ultraviolet Light Sweeping Device claim 2 further comprising a side-opened reflection chamber, the side-opened reflection chamber having an opening at its side, and radiation light is projected outside through the opening. Concentrated Beam UV LED Ultraviolet Light Sweeping Device Claim 14 wherein the polygonal aluminum multi-reflective surface mirror is either a polygonal multi-sided columnar aluminum reflective surface mirror or a polygonal multi-sided irregular columnar aluminum reflective surface mirror. Concentrated Beam UV LED Ultraviolet Light Sweeping Device claim 2 , where the concentrated beam UV LED ultraviolet light bead has a wavelength of 250 - 285 nm for surface sterilization. Concentrated Beam UV LED Ultraviolet Light Sweeping Device Claim 14 , where the condensed beam UV LED ultraviolet light bead has a wavelength of 285 - 350nm for the cultivation of mushrooms and expanses and for phototherapy. Concentrated Beam UV LED Ultraviolet Light Sweeping Device Claim 14 , wherein the bundled beam UV LED ultraviolet light bead has a wavelength of 350 - 405 nm for photopolymerization and curing of a UV resin.

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