This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2012-032137, filed on Feb. 16, 2012; the entire contents of which are incorporated herein by reference.
Exemplary embodiments described herein relate generally to a lighting apparatus.
There has been a lighting apparatus which includes a light emitting element such as a light emitting diode, and a wavelength conversion portion containing a phosphor.
According to such a lighting apparatus, compared to an incandescent lamp, a fluorescent lamp or the like using a filament of the related art, electric power consumption can be reduced and service can be made longer.
According to an aspect, there is provided a lighting apparatus which includes a light source having a light emitting element, and a member to which light emitted from the light source is irradiated and which is formed of resin substantially not containing halogen or phosphorus.
Hereinafter, an example of exemplary embodiment will be described with reference to the drawings. In addition, in the respective drawings, the same components are denoted by the same reference numerals and the detailed descriptions thereof will be suitably omitted.
The lighting apparatus 10 includes a main body portion 12, a reflection portion 14, and a light source 20. The reflection portion 14 is accommodated in the frame-shaped main body portion 12. The reflection portion 14 is provided with a plurality of concave portions 14a. The light sources 20 are each provided inside the respective concave portions 14a.
In addition, the lighting apparatus illustrated in
That is,
A transparent cover 16 is provided above the reflection portion 14. In addition,
The reflection portion 14 and the transparent cover 16 can be formed of resin. Moreover, in the exemplary embodiment, if resin is used as a material of a portion such as the reflection portion 14 and the transparent cover 16 on which light from the light source 20 hits, resin which does not substantially contain halogen or phosphorus is used. This will be described later in detail.
The light source 20 is provided below the concave portion 14a of the reflection portion 14. The light source 20 has a metallic support substrate 22 and an insulating layer 24 that covers the surface thereof. An mounting pad 26 and an electrode pad 28 are each formed over the insulating layer 24. A plurality of light emitting elements 30 is mounted on the mounting pad 26. Such light emitting elements 30 are, for example, connected in series using a metal wire 32, and are connected to both the electrode pads 28 using a wire 34. It is possible to make the light emitting elements 30 shine by causing the electric current to flow between the pair of electrode pads 28.
As the light emitting element 30, for example, a light emitting diode (LED) can be adopted. When, for example, using a gallium nitride (GaN)-based compound semiconductor as a material of an active layer, it is possible to obtain a short-wavelength light having a wavelength of 500 nanometers or less. However, the material of the active layer is not limited to the gallium nitride-base compound semiconductor.
Furthermore, as the light emitting element 30, in addition to the light emitting diode, for example, it is possible to use an organic light emitting diode (OLED), an inorganic electroluminescence light emitting element, an organic electroluminescence light emitting element, other electroluminescence type light emitting elements or the like.
Silver (Ag) or an alloy containing silver is provided on the surface of the mounting pad 26 and the electrode pad 28. Silver has high reflectivity to a short-wavelength of blue light or the like. Accordingly, by providing silver and silver alloy on the surface of the mounting pad 26 and the electrode pad 28, it is possible to reflect light emitted from the light emitting element 30 at high reflectivity to take the light to the outside.
The light emitting element 30 and the wires 32 and 34 are covered by a wavelength conversion layer 36. The wavelength conversion layer 36 has, for example, a structure in which phosphor is dispersed in resin. The wavelength conversion layer 36 is surrounded by a frame 38 formed therearound. As resin constituting the wavelength conversion layer 36, for example, a silicon-based resin can be adopted as an example. Furthermore, as a material of the frame 38, for example, a silicon-based resin can be used. If the silicon-based resin is used, even when light of a short-wavelength such as blue light or ultraviolet light is emitted from the light emitting element 30, the degradation can be suppressed.
Phosphor included in the wavelength conversion layer 36 absorbs light emitted from the light emitting element 30 and emits light of another wavelength. For example, when blue light of a wavelength of 450 nanometers to 500 nanometers is emitted from the light emitting element 30, it is possible to convert blue light into yellow light by the phosphor.
Thus, white light can be obtained if converting a part of blue light emitted from the light emitting element 30 into yellow light and mixing the yellow light with the blue light emitted to the outside without being converted.
In this manner, light such as white light emitted from the light source 20 can be taken to the outside from the concave portion 14a of the reflection portion 14 via the transparent cover 16. Furthermore, light emitted obliquely from the light source 20 is reflected by a reflection surface 14b serving as the inner wall surface of the concave portion 14a of the reflection portion 14 and can be taken to the outside via the transparent cover 16. However, light taken from the lighting apparatus of the exemplary embodiment is not limited to white light.
As mentioned above, in the exemplary embodiment, when using resin as a material of a portion such as the reflection portion 14 and the transparent cover 16 to which light from the light source 20 hits, resin which does not substantially contain halogen or phosphorus is used. This will be described later in detail.
Moreover, in the exemplary embodiment, when using resin as a material of a portion which is directly or indirectly irradiated by the light source 20, resin which substantially does not contain halogen and phosphorous is used. For example, in the case of the lighting apparatus illustrated in
In this manner, reliability of the lighting apparatus can be improved.
As a specific example of resin usable in the exemplary embodiment, it is possible to adopt, for example, an LCP (Liquid Crystal Polymer), PEI (polyetherimide), PEEK (polyetheretherketone), PPE (Polyphenyleneether), PPO(Polyphenyleneoxide), PBT (Poly Buthylene Terephthalate), PET (Poly Ethylene Terephthalate), PA(Polyamide), PAR (Polyarylate), PC(Polycarbonate) or the like. Moreover, when using any one of these resins, resin which substantially does not contain halogen and phosphorous is used. In this manner, reliability of the lighting apparatus can be improved.
Furthermore, a complex resin containing the resins mentioned above of 50 weight % or more may be adopted. When using the complex resin, it is easy to design heat resistance and incombustibility.
In addition, in the specification, the expression “substantially not containing” refers that the content is zero or even if the content is not zero, the content is within a range which does not affect the product life required for the lighting apparatus. For example, when the life required for the lighting apparatus is forty thousand times, if the life is within an achieved range (for example, about 1000 ppm or more and 2500 ppm or less to the resin gross weight), halogen or phosphorus may be contained.
Hereinafter, an exemplary embodiment will be described in more detail with reference to a comparative example.
The inventors formed a reflection portion 114 of a lighting apparatus having the structure as illustrated in
As a consequence, illumination gradually dropped after the lighting started, and the non-lighting state was obtained at substantially 4000 hours.
That is,
Although the reflection surface 114b was white before the lighting test, the reflection surface 114b after the lighting test turns black and a crack is partially generated. That is, it is understood that the surface of the PBT added with bromine (Br) makes anamorphism. It is understood that reflectivity of the reflection surface 114b drops due to the darkening and the crack, and the illumination of the lighting apparatus drops.
Next,
The light source 200 is formed on a white insulating layer 224 (corresponding to the insulating layer 24), and a light emitting element 230 (corresponding to the light emitting element 30) sealed in a wavelength conversion layer 236 (corresponding to the wavelength conversion layer 36) is provided in a frame 238 (corresponding to the frame 38). The light emitting element 230 is mounted on a mounting pad 226 (corresponding to the mounting pad 26). Furthermore, electrode pads 228 (corresponding to the electrode pad 28) are provided at both sides of the mounting pad 226 and are connected to the light emitting element 230 using a wire. The surfaces of the mounting pad 226 and the electrode pad 228 are covered by silver.
A left end portion and a right portion of the mounting pad 226 illustrated in
After checking a portion of the electrode pad 228 in detail, it was understood that a darkened surface layer of the electrode pad 228 is peeled and a bonding portion of the wire is also peeled. That is, it was proved that the wire enters the disconnection state, and non-lighting state is obtained.
The peeled piece 400 has a surface layer of the mounting pad 226, a surface layer of the electrode pad 228, a wavelength conversion layer 236 sealing therearound, and a part of a frame 238.
In this manner, in darkened portions of the mounting pad 226 and the electrode pad 228, the surfaces thereof make anamorphism and are simply peeled.
The surface layer of the peeled electrode pad 228 becomes black and exhibits an outline condensed in a particle shape. Furthermore, the wire 234 is also peeled from the remaining portion (a portion remained over the insulating layer 224) of the electrode 228. That is, it is understood that sliver of the electrode pad 228 performs anamorphism.
That is,
Although a material of the wire 234 is gold (Au), the surface thereof becomes alloy by being bonded to a silver layer of the electrode pad 228. Moreover, a structure of a condensed particle shape is also seen on the surface of the peeled wire 234. As a result of EPMA (Electron Probe Micro Analysis), it was understood that the structure of the particle shape contains silver.
That is, it is understood that anamorphism of silver occurs on a bonding interface between the wire 234 and the electrode pad 228.
Herein, as in the peeled piece 400 illustrated in
In the comparative example, even in the peeled piece 400 side (
On the contrary, in the lighting apparatus of the exemplary embodiment, even at the side (
From the analysis result, it is understood that, in the comparative example, bromine or the compound containing bromine is detached from the reflection portion 114 during lighting test, bromine or the compound containing bromine reaches the surface of the electrode pad 228 and reacts with silver, and silver bromide is formed. Moreover, in the process when silver bromide is formed in this manner, as illustrated in
Furthermore, it is considered that bromine or the compound containing bromine is detached from the reflection portion 114, thus as illustrated in
Furthermore,
In addition,
Furthermore,
When examining the light emitting spectrum ES of light that is emitted from the light source 200, blue light having a peak of a wavelength of about 450 nanometers and broad yellow light having a peak of a wavelength of about 560 nanometers are included.
Meanwhile, the absorption spectrum AS of PBT containing bromine illustrates a transition in which absorptivity suddenly rises at the short wavelength side as a boundary of a wavelength of about 420 nanometers in an initial state. However, after being maintained for 120 hours at 150° C., absorptivity rises over a wide range of a wavelength from 400 nanometers to 700 nanometers.
In addition, when examining the absorption spectrum CS of the reflection portion 114 in which aluminum is deposited as a reference example, at the wavelength side that is longer than the wavelength of 440 nanometers, absorptivity is higher than the PBT containing bromine of the initial state. However, it is understood that there is no sudden increase of absorptivity even in the wavelength that is equal to or less than the range, and low absorptivity is maintained at the short wavelength side.
It is understood from
Moreover, when the decomposition and anamorphism of the PBT containing bromine occur, as illustrated in
The problem is not actualized in a visible ray, if a light quantity and a temperature are low. However, the problem can be actualized in the large light quantity light source and the element near the light source.
Furthermore, when the decomposition and anamorphism of the PBT containing bromine occur, bromine or the compound containing bromine is detached and reacts with silver of the electrode pad and the mounting pad, and darkening, cohesion, peeling or the like occurs.
Particularly, in a lighting appliance in which the light source and the reflection portion are placed in a space sealed by a cover or the like, the detached gas ingredients can be filled and the problem can easily occur.
Thus, in order to prevent the degradation of resin from the initial state, there is a need to lower absorptivity of light emitted from the light source as possible.
Light L including ingredients of the short wavelength is emitted from the light source 200, and a part thereof is reflected by the reflection surface 114b of the reflection portion 114 and is taken to the outside. When the reflection portion 114 contains halogen and phosphorus, if light of the short wavelength is emitted, the decomposition and the anamorphism occur, and halogen and phosphorus or the compound thereof is detached from the reflection portion 114.
Furthermore, the decomposition and the anamorphism in the reflection portion 114 can also be promoted by the temperature. In addition, as illustrated in
As a consequence of the decomposition and the anamorphism, in
Furthermore, it is also possible to consider that, before or after the organic matter R—Br reaches the mounting pad 226 and the electrode pad 228, the organic matter is decomposed by light of the short wavelength emitted from the light emitting element 230, and the more active bromine ion is formed.
In addition, although a situation of containing bromine has been described as an example in the specific example mentioned above, the exemplary embodiments are not limited thereto. The reason is why, like bromine, halogen or phosphorus other than bromine also reacts with silver, and causes darkening, the cohesion, the disconnection or the like.
According to the mechanism mentioned above, the irradiation of light and the rise of the temperature cause the decomposition and the anamorphism of resin, and as a consequence, halogen and phosphorus or the compound thereof is detached. Moreover, the detached halogen and phosphorus or the compound thereof react with silver of the electrode pad and the mounting pad, which causes the drop of illumination, the disconnection of the wire or the like.
On the contrary, in the present embodiment, when using resin in the portion on which light from the light source 20 hits, resin substantially not containing halogen and phosphorous is adopted. A specific example of the resin is as mentioned above.
Furthermore, in some cases, halogen and phosphorus are added to improve incombustibility of resin. Moreover, in the lighting apparatus, since the temperature of the light source rises, resin requires predetermined incombustibility. Thus, in the exemplary embodiment, it is desirable to use resin which does not substantially contain halogen or phosphorus and has predetermined level of incombustibility.
Specifically, for example, it is desirable to use resin which has a grade in the UL 94 standard of a V-1 grade or more, that is, corresponding to some grades of V-1, V-0, 5VB, and 5VA.
That is,
The lighting apparatus 50 of the exemplary embodiment is a so called “electric bulb type” and can be used in an appliance which uses a filament type electric bulb of the related art as it is.
A metal cap portion 54 is provided in a base of a main body portion 52 and can be screwed into the lighting appliance instead of the electric bulb of the related art.
A transparent or semitransparent cover 56 is provided on the main body portion 52. A power source substrate 58 is accommodated in the main body portion 52. Furthermore, an installation substrate 60 is fixed to the vicinity of the upper end of the main body portion 52, and a light source 62 is provided thereon. The light source 62 corresponds to the light source 20 in the specific example illustrated in
A connection member 64 is provided on the installation substrate 60. The connection member 64 is, for example, a connector, and connects a wiring 66 connected to the power source substrate 58 with the light source 62. The wiring 66 has a structure in which a core line of a conductor is covered by an insulator.
In the exemplary embodiment, for example, the coating or the like of the connection member 64 and the wiring 66 is formed of resin which does not substantially contain halogen or phosphorus. In the manner, it is possible to prevent that resin constituting the coating or the like of the connection member 64 and the wiring 66 is decomposed and performs anamorphism, and halogen, phosphorus or the compound thereof is detached and reacts with silver of the mounting pad and the electrode pad provided in the light source 62, and darkening, the cohesion, the disconnection or the like occurs.
As a consequence, it is possible to provide a lighting apparatus having high reliability.
In addition, in the case of the specific example illustrated in
Furthermore, the shape and the arrangement of the connection member 64 and the wiring 66 are not limited to the illustrated specific example. For example, the connection member 64 may be a “contact point connector” which is provided around the light source in a frame shape and is connected via a contact point.
In addition, in the exemplary embodiment, the member to be formed of resin, which does not substantially contain halogen or phosphorus, are not limited to the reflection portion, the connection member, and the wiring. That is, the members may be directly or indirectly irradiated with light emitted from the light source. For example, the members correspond to the main body portion, the installation substrate, the transparent cover, and in addition, various elements provided in the lighting apparatus.
In the lighting apparatus illustrated in
The diffusion restriction layer 70 preferably has a material and a structure which have high transmissivity to light emitted from the light source 20 and are able to maintain a certain degree of airtightness. As a material of the diffusion restriction layer 70, an organic material, an inorganic material or the like can be used. The diffusion restriction layer 70 can be formed by applying, curing and drying a liquid organic material or inorganic material so as to cover the light source 20. In this case, as a raw material of the diffusion restriction layer 70, a water glass or the like can be used.
In addition, it is not required to necessarily form the diffusion restriction layer 70 so as to come into contact with the light source 20. That is, the diffusion restriction layer 70 may cover the periphery of the light source 20, and may prevent the ingredients, which is detached from resin, from entering inside the light source 20. For this reason, for example, as in a filter 80 described in
Next, in the lighting apparatus illustrated in
For example, if resin having the absorption spectrum of the initial state of the PBT illustrated in
In addition, in the exemplary embodiment, as in the diffusion restriction layer 70 illustrated in
Next, in the lighting apparatus illustrated in
In addition, although
Next,
The lighting apparatus of the exemplary embodiment mainly has a radiator 9, a light source 40 and a frame 8.
The radiator 9 is provided with a plurality of radiation fins 21. Furthermore, the radiator 9 has a cylindrical side wall portion 18. An outer wall of the side wall portion 18 is also provided with a plurality of radiation fins 21.
The light source 40 has a substrate 41, and an LED element 42 which is implemented on the substrate 41 and is covered by a wavelength conversion layer. A back surface of an opposite side of the implementation surface with the LED element 42 implemented thereon in the substrate 41 comes into contact with a substrate support surface 11 of the radiator 9.
The LED element 42 is implemented so that a emitted surface of light faces the opposite side of the implementation surface of the substrate 41. Furthermore, a connector (not illustrated) is also implemented on the implementation surface of the substrate 41. An electric cable 46 is connected to the connector.
The electric cable 46 is connected to a terminal block 92 illustrated in
The frame 8 functions as a clock decorative rim that covers an inner surface and a lower end portion of the side wall portion 18 of the radiator 9. Furthermore, the frame 8 also has a function of controlling a light distribution or shading of light that is emitted from the light source 40.
The frame 8 has a cylinder portion 61 which is superimposed on the inside of the side wall portion 18 of the radiator 9. The cylinder portion 61 surrounds a lower space of the light source 40. A lower end portion 63 bent outward the cylinder portion 61 is provided in the lower end of the cylinder portion 61. The lower end portion 63 is formed in a ring shape and covers the lower end of the side wall portion 18 of the radiator 9.
As illustrated in
The reflection plate 51 is superimposed on the substrate 41 of the light source 40 so as to face the LED element 42 from the optical guide hole 53. An inner wall surface of the optical guide hole 53 functions as a reflection surface.
Furthermore, a light transmission cover 54 is provided in the inner space of the cylinder portion 61 so as to cover the reflection plate 51.
In the outer wall of the side wall portion 18 of the radiator 9, as illustrated in
Moreover, the lighting apparatus of the exemplary embodiment is attached to an implementation hole provided on a ceiling using elasticity of three installation springs 83. That is, the lighting apparatus of the exemplary embodiment is a down light type lighting apparatus.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Number | Date | Country | Kind |
---|---|---|---|
2012-032137 | Feb 2010 | JP | national |