JP2020167147A - Ultraviolet radiation device and illuminating device - Google Patents

Abstract

To provide an ultraviolet radiation device in which it may be confirmed whether or not it is emitting ultraviolet ray.SOLUTION: An ultraviolet radiation device 10 comprises a light source 11, and a case 16 housing the light source 11. The case 16 has an ultraviolet radiation region 30 for radiating an ultraviolet ray having a wavelength of 300 nm or less, and a visible light radiation region 31 for radiating visible light when the ultraviolet ray is radiated from the ultraviolet radiation region 30.SELECTED DRAWING: Figure 1

Description

Embodiments of the present invention relate to an ultraviolet emitting device and a lighting device that emit ultraviolet rays.

Conventionally, for example, an ultraviolet lamp that emits ultraviolet rays for the purpose of sterilization has been used. As the ultraviolet lamp, a discharge lamp type has been used, but replacement with a light emitting element such as an LED that emits ultraviolet rays is being considered.

In the case of a discharge lamp type ultraviolet lamp, visible light is emitted together with the emission of ultraviolet rays, so it was possible to confirm whether or not the ultraviolet rays were emitted. On the other hand, in the case of a light emitting element for ultraviolet rays, only ultraviolet rays are radiated and visible light is not radiated, so that it is difficult to confirm whether or not ultraviolet rays are radiated.

Special Table 2018-5247883

An object of the present invention is to provide an ultraviolet emitting device and a lighting device capable of confirming whether or not ultraviolet rays are emitted.

The ultraviolet radiating device of the embodiment includes a light source and a housing for accommodating the light source. The housing includes an ultraviolet radiation region that emits ultraviolet rays having a wavelength of 300 nm or less, and a visible light radiation region that emits visible light when ultraviolet rays are emitted from the ultraviolet radiation region.

According to the ultraviolet radiating device of the embodiment, it can be confirmed whether or not the ultraviolet rays are radiated.

It is a schematic side surface part of the ultraviolet radiation apparatus which shows 1st Embodiment. It is the schematic sectional drawing of the ultraviolet radiation apparatus as above. It is a perspective view of the lighting device using the same-mentioned ultraviolet radiation device. It is a graph of the emission spectrum of the discharge lamp type germicidal lamp. It is a graph of the emission spectrum of the ultraviolet emission element of the ultraviolet emission apparatus and the ultraviolet absorption spectrum of DNA of the same as above. It is a perspective view of the ultraviolet radiation apparatus which shows the 2nd Embodiment. It is a perspective view of the ultraviolet radiation apparatus which shows the 3rd Embodiment. It is a schematic side view of the ultraviolet radiation apparatus which shows the 4th Embodiment. It is schematic cross-sectional view of the visible light light emitting element of the same above-mentioned ultraviolet radiation apparatus. It is a circuit diagram which shows 1st example of the connection circuit of the ultraviolet radiation apparatus of the same as above. It is a circuit diagram which shows the 2nd example of the connection circuit of the ultraviolet radiation apparatus as above. It is sectional drawing of the ultraviolet radiation apparatus which shows 5th Embodiment. It is a perspective view of the disassembled state of the ultraviolet radiation apparatus which shows 6th Embodiment. It is sectional drawing of the assembled state of the ultraviolet radiation apparatus as above. It is a perspective view of the disassembled state of the ultraviolet radiation apparatus which shows 7th Embodiment. It is the perspective view of the assembled state of the ultraviolet radiation apparatus as above. It is sectional drawing of the ultraviolet radiation apparatus which shows the 8th Embodiment. It is sectional drawing of the ultraviolet radiation apparatus which shows the 9th Embodiment. It is the schematic sectional drawing of the ultraviolet radiation apparatus which shows the tenth embodiment. FIG. 19 is a cross-sectional view taken along the line AA of FIG.

Hereinafter, the first embodiment will be described with reference to FIGS. 1 to 5.

1 and 2 show a schematic view of the ultraviolet radiating device 10. The ultraviolet radiation device 10 of the present embodiment shows the form of a straight tube type ultraviolet lamp.

The ultraviolet radiating device 10 includes a light emitting module 11 as a light source, a cover 12 which is a straight tube cover accommodating the light emitting module 11, a phosphor 13 provided at a position where light from the light emitting module 11 is incident, and a cover 12. It includes a power supply base 14 attached to one end and a non-power supply base 15 attached to the other end of the cover 12. A housing 16 for accommodating the light emitting module 11 is configured by a cover 12, bases 14, 15, and the like. Further, the base 14 is a power feeding unit 17 for supplying electric power to the light emitting module 11. The cover 12 shown in each of the drawings below is shown in a transparent state except for a cross-sectional view.

The light emitting module 11 has a substrate 18 and a plurality of ultraviolet light emitting elements 19 mounted on one surface of the substrate 18.

The substrate 18 is formed in an elongated flat plate shape along the longitudinal direction (axial direction) of the straight tube type ultraviolet radiation device 10. The substrate 18 has a substrate base whose main component is an inorganic material such as aluminum nitride (AlN), aluminum oxide (Al ₂ O ₃ ), and silicon nitride (Si ₃ N ₄ ), which are resistant to deterioration by ultraviolet rays. Alternatively, it has a substrate base whose main component is a metal material such as copper (Cu) or aluminum (Al), which has good heat dissipation. A metal wiring pattern 21 of the connection circuit is formed on the surface of the substrate base. A plurality of ultraviolet light emitting elements 19 are mounted on the wiring pattern 21 of the substrate 18. At the end of the substrate 18, a pair of connecting portions 22 for electrically connecting to the feeding portion 17 are provided. The pair of connecting portions 22 are connected to the positive electrode side and the negative electrode side of the wiring pattern 21, respectively. The pair of connecting portions 22 may be a part of the wiring pattern 21 or may be a metal connector.

The ultraviolet light emitting element 19 is mounted on the wiring pattern 21 of the connection circuit along the longitudinal direction of the substrate 18. The plurality of ultraviolet light emitting elements 19 are connected in series or in series or parallel by a connection circuit. The ultraviolet light emitting element 19 emits ultraviolet rays of 300 nm or less, preferably light in the ultraviolet wavelength range of 260 to 280 nm (hereinafter referred to as ultraviolet rays). As the ultraviolet light emitting element 19, for example, a semiconductor light emitting element such as an LED is used. As the ultraviolet light emitting element 19, a flip chip type that is surface-mounted on the wiring pattern 21 of the substrate 18 may be used. The ultraviolet light emitting element 19 emits only ultraviolet rays and does not emit light in other wavelength ranges including light in the visible light wavelength range (hereinafter referred to as visible light).

Further, the cover 12 is formed in an elongated cylindrical shape along the longitudinal direction of the ultraviolet emitting device 10. The cover 12 is formed mainly of an inorganic material such as quartz glass containing silicon dioxide (SiO ₂ ), which is resistant to deterioration by ultraviolet rays and transmits ultraviolet rays and visible light (visible light). The cover 12 has a translucent portion 12a through which ultraviolet rays and visible light are transmitted. The light transmitting portion 12a is formed in at least a region of the cover 12 in the light irradiation direction.

Further, the phosphor 13 is excited by the incident of ultraviolet rays and emits visible light. The phosphor 13 emits only visible light and does not transmit ultraviolet rays, that is, does not emit ultraviolet rays. The phosphor 13 is provided at a position different from the surface of the ultraviolet light emitting element 19. In the present embodiment, the phosphor 13 is provided in a part of the translucent portion 12a of the cover 12 to which the ultraviolet rays emitted from the ultraviolet light emitting element 19 are incident. The phosphor 13 is a phosphor layer formed by, for example, coating on the inner surface of the translucent portion 12a of the cover 12 to which the ultraviolet rays from the ultraviolet light emitting element 19 are incident. Further, the phosphor 13 is formed along the longitudinal direction of the cover 12, and is formed in a region of, for example, 1/4 or more and 1/2 or less in the circumferential direction of the cover 12. The region where the phosphor 13 is formed in the cover 12 is not limited to such a region, and if the region is a region where the light of the ultraviolet light emitting element 19 is incident, the cover 12 may be partly in the longitudinal direction and part in the circumferential direction. It may be on the outer surface of the cover 12.

Further, the power feeding unit 17 (base 14) has a power feeding unit main body (base body) 23 provided in the housing and a pair of electrodes 24 provided on the power feeding unit main body 23.

The power feeding unit main body 23 is formed of an inorganic material such as metal that is not easily deteriorated by ultraviolet rays. The power feeding unit main body 23 has a cylindrical tubular portion 25 fitted to the cover 12 and an end surface portion 26 provided on the outer end surface of the tubular portion 25. The feeding portion main body 23 may be made of a resin material. In this case, a light-shielding portion may be provided so that ultraviolet rays do not enter the feeding portion main body 23.

The electrode 24 is made of a conductive metal material which is an inorganic material that is not easily deteriorated by ultraviolet rays. The electrode 24 of the present embodiment has a pin shape and projects from the outer end surface of the power feeding unit main body 23 and penetrates inside the feeding unit main body 23. When the power feeding unit main body 23 is made of a metal material, an insulating part 27 made of an insulating inorganic material such as insulating paper or ceramics is formed in a portion through which the electrode 24 of the power feeding unit main body 23 penetrates to supply power. The main body 23 and the electrode 24 are insulated. The electrode 24 is directly connected to the connection portion 22 of the substrate 18. That is, the electrode 24 is directly connected to the wiring pattern 21, or the electrode 24 is inserted and connected to a metal connector mounted on the substrate 18. The electrode 24 of the power feeding unit 17 is not limited to the pin shape, and may have any shape such as a connector shape.

Further, the base 15 has a base body 28 made of an inorganic material such as metal that is fitted and attached to the cover 12, and a metal non-feeding pin 29 projecting from the outer end surface of the base body 28. are doing. The non-feeding pin 29 is used for mounting on the appliance side or for grounding. When used for ground connection, it is configured to be directly connected to the connection portion 22 provided on the substrate 18 in the same manner as the electrode 24 of the power supply portion 17.

Therefore, each part facing the internal space of the ultraviolet radiation device 10 is formed of an inorganic material that is not easily deteriorated by ultraviolet rays, including the connection path from the feeding portion 17 to the ultraviolet light emitting element 19 of the substrate 18.

The ultraviolet radiation device 10 includes an ultraviolet radiation region 30 that emits ultraviolet rays, and a visible light radiation region 31 that emits visible light when ultraviolet rays are emitted from the ultraviolet radiation region 30. The ultraviolet radiation region 30 and the visible light radiation region 31 are provided separately in different regions of the housing 16. The ultraviolet radiation region 30 and the visible light radiation region 31 are provided in the translucent portion 12a of the cover 12. The ultraviolet radiation region 30 is provided in a region of the cover 12 where the phosphor 13 of the translucent portion 12a is not provided. The visible light emitting region 31 is provided in the region of the cover 12 where the phosphor 13 of the translucent portion 12a is provided.

At least a part of the ultraviolet radiation region 30 and the visible light radiation region 31 may overlap.

Further, the ultraviolet radiation region 30 refers to an region configured to intentionally emit ultraviolet rays. For example, when comparing the light in the ultraviolet region of 380 nm or less and the light in the visible light region of 380 nm to 780 nm in a spectral spectrum, the light emitted from the ultraviolet radiation region 30 is more visible in the intensity of the light in the ultraviolet region. It becomes relatively stronger than the intensity of light in the light region. The light intensity here may be the peak intensity of each region, the radiant flux, or the radiant intensity.

Further, the visible light radiation region 31 refers to a region configured to intentionally emit visible light. For example, when comparing the light in the ultraviolet region of 380 nm or less and the light in the visible light region of 380 nm to 780 nm in a spectral spectrum, the light emitted from the visible light radiation region 31 has a higher intensity of light in the visible light region. , It becomes relatively stronger than the intensity of light in the ultraviolet region. The light intensity here may be the peak intensity of each region, the radiant flux, or the radiant intensity.

Further, FIG. 3 shows a lighting device 37 using the ultraviolet radiation device 10. The lighting device 37 has an elongated fixture body 38. At both ends in the longitudinal direction of the instrument main body 38, a power supply socket 39 and a non-power supply socket 40 to which the power supply unit 17 (base 14) and the base 15 of the ultraviolet radiation device 10 are mounted are arranged. For example, a power supply device 41 that converts AC power into predetermined DC power and supplies it to the ultraviolet radiating device 10 is arranged in the appliance main body 38.

Then, the electric power converted by the power supply device 41 is supplied to the light emitting module 11 through the power feeding socket 39 and the power feeding unit 17, so that the plurality of ultraviolet light emitting elements 19 of the light emitting module 11 emit light. Ultraviolet rays are emitted from a plurality of ultraviolet light emitting elements 19, and the ultraviolet rays are transmitted to the outside through the ultraviolet radiation region 30 of the cover 12.

Here, FIG. 4 shows a graph of the emission spectrum of the discharge lamp type germicidal lamp, and FIG. 5 shows a graph of the emission spectrum of the ultraviolet light emitting element 19 and the ultraviolet absorption spectrum of the DNA.

The discharge lamp type germicidal lamp for the purpose of sterilization has a peak wavelength of 254 nm. Since the ultraviolet absorption spectrum of DNA has an absorption peak wavelength of 260 nm, a sterilizing effect can be efficiently obtained by using a germicidal lamp.

The ultraviolet absorption spectrum of DNA has an absorption peak wavelength at 260 nm, and at 300 nm, the absorption value is less than 1/25 of the peak value. Therefore, ultraviolet rays of 300 nm or less are preferable.

Therefore, the peak wavelength of the ultraviolet light emitting device 19 is preferably 300 nm or less, more preferably 260 nm to 280 nm corresponding to the peak wavelength region of the ultraviolet absorption spectrum of DNA, thereby efficiently obtaining a bactericidal effect. be able to.

Further, a part of the ultraviolet rays from the ultraviolet light emitting element 19 is incident on the phosphor 13 formed on the cover 12. The phosphor 13 is excited by the incident of ultraviolet rays to emit visible light, and this visible light is transmitted to the outside through the visible light emitting region 31 of the cover 12.

Therefore, when the ultraviolet emitting device 10 is lit, that is, when the ultraviolet rays are emitted from the ultraviolet emitting region 30, visible light is always emitted from the visible light emitting region 31. By visually recognizing the radiated light from the visible light radiating region 31 of the cover 12, it can be confirmed that the ultraviolet rays are emitted from the ultraviolet radiating device 10.

Then, according to the ultraviolet radiation device 10, when the ultraviolet rays are radiated from the ultraviolet radiation region 30, visible light is radiated from the visible light radiation region 31, so that it can be confirmed whether or not the ultraviolet rays are radiated.

Since the ultraviolet radiation region 30 and the visible light radiation region 31 are divided into different regions, it is possible to easily confirm whether or not ultraviolet rays are emitted.

Further, when the wavelength of the ultraviolet rays emitted from the ultraviolet radiation region 30 is 300 nm or less, the bactericidal effect can be efficiently obtained.

Further, since the phosphor 13 is provided at a position different from the surface of the ultraviolet light emitting element 19, it is difficult to receive the heat of the ultraviolet light emitting element 19 and it is possible to prevent deterioration.

Further, since the phosphor 13 is provided in the housing 16, that is, because it is provided in a part of the translucent portion 12a of the cover 12, ultraviolet rays from the ultraviolet light emitting element 19 are likely to be incident on the housing 16. It is possible to easily check the visible light from the outside.

Next, FIG. 6 shows a second embodiment.

The ultraviolet radiating device 10 includes a second cover 44 which is attached so as to cover the outer periphery of the cover 12. The second cover 44 constitutes a part of the housing 16. The second cover 44 is formed mainly of an inorganic material such as borosilicate glass, which is resistant to deterioration by ultraviolet rays and does not transmit ultraviolet rays but transmits visible light. The second cover 44 is formed in a substantially C-shaped cross section having an irradiation opening 45 along the longitudinal direction. The ultraviolet rays emitted by the ultraviolet light emitting element 19 are irradiated to the outside through the irradiation opening 45 of the second cover 44, that is, the ultraviolet radiation region 30. The opening width of the irradiation opening 45 of the second cover 44 is preferably equal to or larger than the width of the ultraviolet light emitting element 19 so that the ultraviolet rays can efficiently pass to the outside.

The phosphor 13 is provided not on the cover 12, but on the inner surface, the outer surface, or the inside (such as a translucent sintered body such as borosilicate glass mixed with the phosphor) of the second cover 44.

Then, in the ultraviolet radiation device 10, when the ultraviolet light emitting element 19 emits light and emits ultraviolet rays, the phosphor 13 of the second cover 44 is excited by the ultraviolet rays to emit visible light, and the visible light radiation region. Since it radiates from 31 to the outside, it can be confirmed whether or not ultraviolet rays are radiated.

The second cover 44 may be formed mainly of an inorganic material that is not easily deteriorated by ultraviolet rays and that transmits ultraviolet rays and visible light. In this case, the second cover 44 may be formed in a tubular shape without providing the irradiation opening 45, or may be formed in a ring shape having an axial width smaller than, for example, a radial dimension. ..

Next, FIG. 7 shows a third embodiment.

The phosphor 13 is provided on the substrate 18. The phosphor 13 is a surface on which the ultraviolet light emitting element 19 of the substrate 18 is mounted, and is provided at one location, for example, on the end side. The phosphor 13 may be provided at a plurality of locations on the substrate 18.

Then, in the ultraviolet emitting device 10, when the ultraviolet emitting element 19 emits light and emits ultraviolet rays, the phosphor 13 of the substrate 18 is excited by the ultraviolet rays to emit visible light, and the visible light is emitted from the visible light emitting region 31 to the outside. It is possible to confirm whether or not ultraviolet rays are radiated because it radiates to.

An optical guide for guiding the visible light emitted from the phosphor 13 of the substrate 18 to the visible light emitting region 31 of the cover 12 may be used. The light guide may be a tubular body or a light guide body, and may be made of a material that is not easily deteriorated by ultraviolet rays.

Next, FIGS. 8 to 11 show a fourth embodiment.

As shown in FIG. 8, the ultraviolet emitting device 10 includes an ultraviolet emitting element 19 that emits ultraviolet rays toward an ultraviolet emitting region 30 and a visible light emitting element 20 that emits visible light toward a visible light emitting region 31. I have.

The visible light emitting element 20 is mounted on the wiring pattern 21 of the substrate 18 together with the plurality of ultraviolet light emitting elements 19. The visible light emitting element 20 is arranged, for example, on the farthest end side of the plurality of ultraviolet light emitting elements 19 arranged in the longitudinal direction of the substrate 18, and is connected in series or in series to the plurality of ultraviolet light emitting elements 19. The visible light emitting element 20 emits visible light of, for example, 400 to 700 nm. As the visible light emitting element 20, for example, a semiconductor light emitting element such as an LED is used.

As shown in FIG. 9, the visible light light emitting element 20 uses a bonding wire connection type light emitting element package. The visible light emitting element 20 includes a case 48, a pair of lead frames 49 provided in the case 48, a light emitting element unit 50 that emits visible light arranged in one lead frame 49, and each lead frame 49 and a light emitting element unit. It has a bonding wire 51 that electrically connects the 50, and a translucent coating material 52 that covers the lead frame 49, the light emitting element portion 50, and the bonding wire 51 inside the case 48. The visible light emitting element 20 is mounted by connecting a pair of lead frames 49 to the wiring pattern 21 of the substrate 18.

As described above, by using the bonding wire connection type light emitting element package for the visible light light emitting element 20, the bonding wire 51 is blown and electrically opened in the event of a short circuit failure of the visible light light emitting element 20. Therefore, in the event of a short-circuit failure of the visible light emitting element 20, the ultraviolet emitting element 19 is always turned off, and even though the visible light emitting element 20 is turned off, the ultraviolet emitting element 19 emits ultraviolet rays. Can be reliably prevented.

Further, in the visible light emitting element 20, only the light emitting element portion 50 exists as an electronic component, and no other electronic component exists. For example, in general, an electrostatic protection element such as a Zener diode may be connected in parallel with a light emitting element, but an electronic component such as an electrostatic protection element is not connected in parallel to the visible light light emitting element 20.

This is because the electrostatic protection element may be short-circuited, and if the electrostatic protection element is short-circuited, the visible light emitting element 20 is turned off even though the ultraviolet light emitting element 19 emits ultraviolet rays. Because. Therefore, in the visible light emitting element 20, only the light emitting element portion 50 exists as an electronic component, and no other electronic component exists, so that the visible light emitting element 20 is turned off. It is possible to reliably prevent the ultraviolet rays from being emitted from the ultraviolet light emitting element 19.

The ultraviolet light emitting element 19 may be provided with an electrostatic protection element.

Further, FIG. 10 shows a first example of the connection circuit 55 formed on the substrate 18. The connection circuit 55 connects a plurality of ultraviolet light emitting elements 19 and visible light light emitting elements 20 in series and parallel. The connection circuit 55 has a plurality of parallel connection circuit units 56 connected in parallel. A plurality of ultraviolet light emitting elements 19 and at least one visible light light emitting element 20 are connected in series to each of the parallel connection circuit units 56. Therefore, a plurality of sets of light emitting element circuits in which a plurality of ultraviolet light emitting elements 19 and one visible light light emitting element 20 are paired are connected in series and parallel between the positive electrode side and the negative electrode side of the wiring pattern 21.

In this way, when the connection circuit 55 has a plurality of parallel connection circuit units 56 connected in parallel, a plurality of ultraviolet light emitting elements 19 and visible light light emitting elements 20 are connected in series for each parallel connection circuit unit 56. Therefore, even if a failure such as disconnection of the ultraviolet light emitting element 19 or the visible light emitting element 20 occurs in any of the parallel connection circuit units 56, the visible light emitting element 20 is turned off and an abnormality of the ultraviolet emitting device 10 is confirmed. be able to.

Further, the visible light emitting element 20 has a smaller number than the ultraviolet light emitting element 19, or has a relationship in which at least one of the forward voltage and the light emission intensity is smaller. Since it is sufficient for the visible light emitting element 20 to confirm that the ultraviolet emitting device 10 emits ultraviolet rays, it is possible to suppress an increase in power consumption and an increase in price by having such a relationship.

Further, FIG. 11 shows a second example of the connection circuit 55 formed on the substrate 18. The connection circuit 55 connects a plurality of ultraviolet light emitting elements 19 and visible light light emitting elements 20 in series and parallel. The connection circuit 55 has a plurality of parallel connection circuit units 56 connected in parallel. For each parallel connection circuit unit 56, at least one of the ultraviolet light emitting circuit units 57 (two are shown in FIG. 11) in which a plurality of ultraviolet light emitting elements 19 are connected in parallel, and at least one visible light emitting element 20 Each is connected in series. Further, a plurality of parallel connection circuit units 56 and at least one visible light emitting element 20 are connected in series and parallel.

Since the ultraviolet light emitting element 19 that emits ultraviolet rays has a shorter life than the visible light emitting element 20, the ultraviolet rays emitted from the ultraviolet light emitting element 19 are reduced even if the visible light emitting element 20 is lit. Therefore, the visible light emitting element 20 has a circuit configuration in which one visible light emitting element 20 is connected to each of the ultraviolet emitting circuit unit 57 or the plurality of parallel connecting circuit units 56 in which a plurality of ultraviolet light emitting elements 19 are connected in parallel. By doing so, the visible light emitting element 20 has a high load, the life is equal to or less than that of the ultraviolet light emitting element 19, and the life of the ultraviolet light emitting element 19 can be confirmed.

In this ultraviolet emitting device 10, since the ultraviolet emitting element 19 and the visible light emitting element 20 are connected in series, whether or not the visible light emitting element 20 is lit determines whether or not ultraviolet rays are emitted. Can be confirmed.

Further, the visible light emitting element 20 is turned off by using a bonding wire connection type light emitting element package for the visible light emitting element 20, and further, because the electrostatic protection element is not connected to the visible light emitting element 20. Nevertheless, it is possible to reliably prevent the ultraviolet light from being emitted from the ultraviolet light emitting element 19.

Next, FIG. 12 shows a fifth embodiment.

The ultraviolet radiation device 10 includes a motion sensor 60 and a power supply device (lighting device) 61.

The motion sensor 60 faces the inside of the cover 12 and is mounted on the substrate 18, and operates by receiving power supplied from the power supply device 61. The motion sensor 60 detects infrared rays radiated by a person through the cover 12 and outputs a detection signal, which is a signal for stopping the supply of power to the ultraviolet light emitting element 19, to the power supply device 61. The motion sensor 60 is housed in a case 60a made of an inorganic material, and detects a person through a translucent portion provided in at least a part of the case 60a.

The power supply device 61 is housed inside the power supply unit 17, and is electrically connected between the electrode 24 of the power supply unit 17 and the substrate 18 of the light emitting module 11. The power supply device 61 includes a power supply board 62 and a plurality of power supply components 63 constituting the power supply circuit mounted on the power supply board 62. The power supply device 61 converts, for example, an AC power source into a predetermined DC power source and supplies it to the ultraviolet light emitting element 19. The substrate 18 of the light emitting module 11 and the power supply substrate 62 may be integrated or separate, and the connection portion 22 electrically connected to the electrode 24 of the power supply portion 17 is provided on the power supply substrate 62 side. Although the power supply device 61 is arranged in the internal space of the ultraviolet radiation device 10, the ultraviolet light emitting element 19 of the light emitting module 11 is shielded by the motion sensor 60, and the ultraviolet rays from the ultraviolet light emitting element 19 are reduced. Has been done.

Then, the power supply device 61 supplies power to the ultraviolet light emitting element 19 of the light emitting module 11 in a state where the detection signal from the motion sensor 60 is not input, and the detection signal from the motion sensor 60 is input. Then, the supply of power to the ultraviolet light emitting element 19 is stopped.

Therefore, in the lighting device 37 that uses the ultraviolet radiation device 10, when a person enters the ultraviolet irradiation area, the ultraviolet radiation is automatically stopped, and when a person leaves the ultraviolet irradiation area, the ultraviolet rays are emitted. Radiation is automatically resumed. As a result, it is possible to prevent the person from being irradiated with ultraviolet rays from the lighting device 37 that uses the ultraviolet radiation device 10.

The power supply device 61 may be arranged outside the ultraviolet radiation device 10, and the detection signal from the motion sensor 60 included in the ultraviolet radiation device 10 may be output to the external power supply device 61.

Such a configuration using the motion sensor 60 can be applied to both the embodiment using the phosphor 13 described above and the embodiment using the visible light emitting element 20.

Next, a sixth embodiment is shown in FIGS. 13 and 14.

The connection portion 22 provided on the substrate 18 of the light emitting module 11 is composed of a part of the wiring pattern 21. Alternatively, the connection portion 22 is composed of a connection terminal, a connection layer, or the like provided on the wiring pattern 21.

The pair of electrodes 24 of the feeding portion 17 are electrically directly connected and fixed to the pair of connecting portions 22 of the substrate 18. The pair of electrodes 24 of the feeding portion 17 are made of, for example, a conductive metal, and are provided integrally with the feeding portion main body 23 by, for example, insert molding so as to penetrate the feeding portion main body 23. The pair of electrodes 24 are an electrode pin portion 66 protruding from the outer end surface of the feeding portion main body 23, a terminal portion 67 protruding from the inner end surface of the feeding portion main body 23 and directly connected to the connecting portion 22 of the substrate 18, and an electrode pin. It has a bent portion 68 that is bent between the portion 66 and the terminal portion 67 and arranges the terminal portion 67 on the center side of the feeding portion main body 23 rather than the electrode pin portion 66.

The electrode pin portion 66 has a plate-like shape and has an L-shaped bent portion 69 at the tip thereof, so that the bent directions of the bent portions 69 are opposite to each other by the pair of electrodes 24. It protrudes from the power feeding unit body 23.

The terminal portion 67 is provided in a bifurcated shape, and a groove portion 70 into which the end portion of the substrate 18 is inserted is provided between the bifurcated portions. The terminal portion 67 is mechanically fixed by sandwiching the end portion of the substrate 18 to be inserted into the groove portion 70 from the plate thickness direction, and is electrically connected by directly contacting the connection portion 22 of the substrate 18.

The bent portion 68 is provided in a plate shape continuous from the electrode pin portion 66, and is inserted and arranged in the feeding portion main body 23. The bent portion 68 is bent in a substantially L shape from the electrode pin portion 66 in the direction opposite to the bent portion 69, and is further bent in a substantially L shape so as to be continuous from the tip thereof to the terminal portion 67.

In this ultraviolet radiation device 10, the electrode 24 of the power supply unit 17 is electrically directly connected and fixed to the connection portion 22 of the substrate 18, so that the power supply unit 17 facing the internal space of the ultraviolet radiation device 10 to the substrate 18 The connection path to the ultraviolet light emitting element 19 can be made of an inorganic material that is not easily deteriorated by ultraviolet rays, and deterioration of ultraviolet rays can be prevented. Moreover, the number of parts for electrical connection can be reduced and the assemblability can be improved.

Further, the electrode 24 of the feeding portion 17 is bifurcated, and by sandwiching the end portion of the substrate 18, the electrode 24 is electrically directly connected to the connecting portion 22 of the substrate 18, and the electrode 24 and the substrate 18 are fixed. Therefore, the electrode 24 of the power feeding unit 17 and the substrate 18 can be reliably connected and fixed, and the assembling property can be improved.

The electrode pin portion 66 of the electrode 24 of the feeding portion 17 does not include the bent portion 69, and may have a G13-shaped columnar pin shape.

Such a connection structure between the power feeding unit 17 and the substrate 18 can be applied to both the embodiment using the phosphor 13 and the embodiment using the visible light emitting element 20 described above.

Next, FIG. 15 and FIG. 16 show a seventh embodiment.

The light emitting module 11 has a pair of metal connectors 72 as metal connecting portions 22 provided at the ends of the substrate 18. The pair of connectors 72 are mounted on the wiring pattern 21 at one end in the longitudinal direction of the substrate 18, and are connected to the positive electrode side and the negative electrode side of the wiring pattern 21, respectively. The connector 72 is formed in a substantially tubular shape having an outlet toward the end of the board 18, and is connected to the electrode 24 of the power feeding unit 17 which is inserted into the outlet from the outside of the end of the substrate 18. The contact portion provided with the 72 is elastically contacted, and the electrode 24 is configured to be electrically directly connected and mechanically fixed.

The pair of electrodes 24 of the feeding portion 17 are electrically directly connected and fixed to the pair of connecting portions 22 of the substrate 18. The pair of electrodes 24 of the feeding portion 17 are made of, for example, a conductive metal, and are provided integrally with the feeding portion main body 23 by, for example, insert molding so as to penetrate the feeding portion main body 23. The pair of electrodes 24 have an electrode pin portion 66, a terminal portion 67, and a bent portion 68, as in the sixth embodiment.

The terminal portion 67 is provided in a square columnar shape. The terminal portions 67 of the pair of electrodes 24 are arranged so as to coincide with the central axes of the insertion holes of the pair of connectors 72 of the substrate 18, and are inserted into the pair of connectors 72 and directly connected to each other. The terminal portion 67 is projected from the bent portion 68, and is projected from a position closer to one end in the width direction of the plate surface of the bent portion 68 corresponding to the position of the connector 72 of the substrate 18.

In this ultraviolet radiation device 10, the electrode 24 of the power supply unit 17 is electrically directly connected and fixed to the connection portion 22 of the substrate 18, so that the power supply unit 17 facing the internal space of the ultraviolet radiation device 10 to the substrate 18 The connection path to the ultraviolet light emitting element 19 can be made of an inorganic material that is not easily deteriorated by ultraviolet rays, and deterioration of ultraviolet rays can be prevented. Moreover, the number of parts for electrical connection can be reduced and the assemblability can be improved.

Further, by using the connector 72 as the connecting portion 22 of the substrate 18, the electric feeding portion 17 can be reliably connected and fixed to the electrode 24, and the assembling property can be improved.

The electrode pin portion 66 of the electrode 24 of the feeding portion 17 does not include the bent portion 69, and may have a G13-shaped columnar pin shape.

Such a connection structure between the power feeding unit 17 and the substrate 18 can be applied to both the embodiment using the phosphor 13 and the embodiment using the visible light emitting element 20 described above.

Next, FIG. 17 shows an eighth embodiment.

The ultraviolet radiating device 10 includes a power supply device 61 as in the fifth embodiment. The power supply board 62 of the power supply device 61 and the board 18 of the light emitting module 11 are electrically connected by a power feeding component 75 on one side of the board 18 on which the ultraviolet light emitting element 19 is mounted. Further, on one side of the power supply board 62, the power supply component 75 and the connector 72 of the power supply component 63 and the connection portion 22 are mounted. The substrate 18 of the light emitting module 11 and the power supply substrate 62 may be integrated or separate.

The electrode 24 of the power feeding unit 17 is electrically directly connected to the connector 72 of the connecting unit 22.

The internal space of the ultraviolet radiation device 10 is divided into a space in which the ultraviolet light emitting element 19 is arranged and a space in which the power supply device 61 and the like are arranged, and are shielded from each other by a plate-shaped shielding portion 76.

Then, in the ultraviolet radiation device 10, the space in which the ultraviolet light emitting element 19 is mounted and the space in which other parts such as the power supply device 61 are arranged are shielded by the shielding unit 76 in the internal space of the ultraviolet radiation device 10. Therefore, even when an organic material such as resin is used for other parts such as the power supply device 61, the ultraviolet rays radiated by the ultraviolet light emitting element 19 can be blocked and the deterioration of ultraviolet rays can be prevented.

The motion sensor 60 may be arranged in a space shielded from the ultraviolet light emitting element 19 by the shielding portion 76.

Such a configuration using the shielding portion 76 can be applied to both the embodiment using the phosphor 13 described above and the embodiment using the visible light emitting element 20.

Next, FIG. 18 shows a ninth embodiment.

The ultraviolet radiating device 10 includes a power supply device 61 as in the fifth and eighth embodiments. The power supply board 62 of the power supply device 61 and the board 18 of the light emitting module 11 are electrically connected by a power feeding component 75 on the other side opposite to the one side on which the ultraviolet light emitting element 19 of the board 18 is mounted. Further, on the other side of the power supply board 62, the power supply component 75 and the connector 72 of the power supply component 63 and the connection portion 22 are mounted. The substrate 18 of the light emitting module 11 and the power supply substrate 62 may be integrated or separate.

The electrode 24 of the feeding portion 17 is electrically connected to the connecting portion 22 by the feeding component 79. The power supply component 79 is electrically connected to the connector 72 of the connection portion 22 by using a covered electric wire or the like.

The internal space of the ultraviolet radiation device 10 is partitioned and isolated by a substrate 18 and a power supply substrate 62 into a space in which the ultraviolet light emitting element 19 is arranged and a space on the opposite side thereof.

Then, in the ultraviolet radiating device 10, the power feeding parts 75 and 79, the connector 72 of the connection portion 22, and the power supply are placed in the space on the opposite side of the internal space of the ultraviolet radiating device 10 where the ultraviolet light emitting element 19 is mounted. Since the parts 63 and the like are arranged, the ultraviolet light emitting element 19 radiates even when an organic material such as resin is used for at least a part of these power supply parts 75 and 79, the connector 72 of the connection part 22 and the power supply part 63. It can block ultraviolet rays and reduce ultraviolet deterioration.

Such a shielding structure can be applied to both the above-described embodiment using the phosphor 13 and the embodiment using the visible light emitting element 20.

Next, FIGS. 19 and 20 show a tenth embodiment.

This is a case where the power feeding unit main body 23 of the power feeding unit 17 is formed of an organic material such as resin. In this case, since the power feeding unit main body 23 is likely to be deteriorated by irradiation with ultraviolet rays, a shielding unit 82 that shields ultraviolet rays from the power feeding unit main body 23 is provided in order to prevent deterioration of the power feeding unit main body 23.

The shielding portion 82 includes a phosphor 13 provided on the cover 12 in order to shield ultraviolet rays from the tubular portion 25 of the feeding portion main body 23. The phosphor 13 is provided on the inner surface side of the cover 12 and on the end side of the cover 12 on which the feeding portion 17 is arranged. The phosphor 13 converts the ultraviolet rays emitted from the ultraviolet light emitting element 19 into visible light, and prevents the ultraviolet rays from being directly applied to the tubular portion 25 of the feeding portion main body 23. The phosphor 13 may be provided on the outer surface of the cover 12 or inside the tubular portion 25 of the feeding portion main body 23.

The shielding portion 82 includes a covering portion 83 that covers the inner surface side of the end surface portion 26 of the feeding portion main body 23 in order to shield ultraviolet rays from the end surface portion 26 of the feeding portion main body 23. The covering portion 83 is formed of an inorganic material such as metal, which is not easily deteriorated by ultraviolet rays. A pair of covering portions 83 are provided in a substantially semicircular plate shape. The covering portion 83 is provided integrally with the electrode 24 or is provided separately so that the electrode 24 is inserted and fixed.

On the inner surface side of the power feeding portion main body 23, a pair of substantially semicircular groove portions 84 in which a pair of covering portions 83 are arranged between the feeding portion main body 23 and the tubular portion 25 are provided, and a pair of coverings are provided between the groove portions 84. A partition wall portion 85 that insulates the portion 83 is projected. Since the partition wall portion 85 is thicker than the thickness of the end face portion 26, the influence of deterioration on the end face portion 26 side is small even if it is irradiated with ultraviolet rays.

The shielding unit 82 that shields ultraviolet rays from the feeding unit main body 23 is provided with a shielding film that shields ultraviolet rays different from that of the phosphor 13 on the inner surface side of the feeding unit main body 23, or a shielding member such as a metal plate is provided. You may use it. Further, as the shielding portion 82, soft glass that does not transmit ultraviolet rays may be used on the end side of the cover 12 on which the feeding portion 17 is arranged.

In this ultraviolet radiation device 10, even when the power supply unit main body 23 of the power supply unit 17 is formed of an organic material such as resin, the shielding unit 82 can prevent the ultraviolet rays from being irradiated to the power supply unit main body 23, and the power supply can be supplied. It is possible to suppress the deterioration of ultraviolet rays in the main body 23 and extend the life of the main body 23 of the feeding unit 23 longer than that of the ultraviolet light emitting element 19.

The life of the feeding unit main body 23 is the strength such as the tensile strength or the compressive strength of the feeding unit main body 23. The life of the power feeding unit main body 23 is longer than that of the ultraviolet light emitting element 19 means that the strength of the power feeding unit main body 23 is secured at a predetermined value or more when the radiant flux of the ultraviolet light emitting element 19 is reduced to, for example, 70%. ..

The ultraviolet radiating device 10 of each of the above-described embodiments can be appropriately combined and configured.

Further, the ultraviolet radiation region 30 and the visible light radiation region 31 are not limited to the case where they are provided in the light transmitting portion 12a of the same cover 12, and may be provided in the light transmitting portions of different members.

Further, the ultraviolet radiation device 10 is not limited to the straight tube type ultraviolet irradiation lamp, and may be a light bulb type ultraviolet irradiation lamp or the like. Further, the ultraviolet radiation device 10 is not limited to the form of a lamp, but may be in the form of an integrated lighting fixture or the like.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

10 UV radiant device
11 Light source module
13 Fluorescent material
16 chassis
17 Power supply
18 board
19 Ultraviolet light emitting element
20 Visible light emitting element
22 Connection
23 Power supply body
24 electrodes
30 UV radiation area
31 Visible light emission area
37 Lighting equipment
41, 61 Power supply
49 lead frame
50 Light emitting element
51 Bonding wire
52 Translucent dressing
55 Connection circuit
72 connector
76, 82 Shield

Claims (10)

With a light source;
Accommodates the light source
An ultraviolet radiation region that emits ultraviolet rays with a wavelength of 300 nm or less, and
A visible light radiation region that emits visible light when the ultraviolet rays are radiated from the ultraviolet radiation region,
With a housing that has
An ultraviolet radiating device equipped with. The light source has an ultraviolet light emitting element that radiates the ultraviolet rays.
The ultraviolet emitting device according to claim 1, further comprising a phosphor that is excited by the ultraviolet rays emitted by the ultraviolet emitting element and emits the visible light. The ultraviolet radiating device according to claim 2, wherein the phosphor is provided in the housing. The light source is
The ultraviolet light emitting element that radiates ultraviolet rays and
The visible light emitting element that emits visible light and
A connection circuit that connects the ultraviolet light emitting element and the visible light light emitting element in series,
The ultraviolet emitting device according to claim 1, wherein the ultraviolet radiating device has. The ultraviolet emitting device according to claim 4, wherein the visible light emitting element has a smaller number than the ultraviolet emitting element, or at least one of a forward voltage and a light emission intensity is smaller. The visible light emitting element includes a lead frame, a light emitting element portion, a bonding wire for electrically connecting the lead frame and the light emitting element portion, and a translucent coating material for coating the lead frame, the light emitting element portion, and the bonding wire. The ultraviolet emitting device according to claim 4 or 5, wherein only the light emitting element portion is present as an electronic component in the visible light emitting element. The light source further includes a substrate provided with a connection portion and on which the ultraviolet light emitting element is mounted.
2. The housing includes a power feeding unit main body and an electrode provided on the power feeding unit main body, and the housing has a power feeding unit in which the electrode contacts the connecting portion of the substrate and is electrically connected. 6. The ultraviolet emitting device according to any one of 6. The ultraviolet emitting device according to claim 7, wherein the connecting portion has a connector into which the electrode is inserted on the other side of the substrate opposite to the one side on which the ultraviolet light emitting element is mounted. The ultraviolet radiation device according to claim 7 or 8, further comprising a shielding portion that shields the ultraviolet rays from the feeding unit main body so that the life of the feeding unit main body is longer than that of the ultraviolet light emitting element. With the ultraviolet emitting device according to any one of claims 1 to 9;
With a power supply device that supplies power to the ultraviolet radiation device;
A lighting device characterized by being provided with.

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