The present invention relates to an optical member for refracting the light, which is emitted from a light source such as a light emitting diode (LED) or the like, through the use of a reflecting plate or a lens and projecting the light from a light projecting surface, and an illumination apparatus using the optical member.
In a conventional illumination apparatus, it is sometimes the case that the light is not uniformly projected from a light projecting surface, thereby generating illuminance unevenness or color unevenness which leads to a failure to make the illuminance of an irradiated surface uniform. Various kinds of devices and methods are used in an effort to reduce the illuminance unevenness.
For example, there is known a method of reducing illuminance unevenness or color unevenness on an irradiated surface by providing dimple-shaped concave portions 7a on a light projecting surface of an optical member of an illumination apparatus as shown in
In order to reduce generation of illuminance unevenness in an illumination apparatus, there is disclosed an illumination apparatus including a molded body for a light source cover which is resistant to resin degradation and capable of realizing a light-irradiated surface with reduced brightness unevenness and enhanced brightness uniformity (see, e.g., Japanese Patent Application Patent No. 2009-76343).
However, even if the illumination apparatus employs the conventional optical member 7 in which the concave portions 7a are arranged on the light projecting surface in a honeycomb structure, a problem is posed in that illuminance unevenness is generated on the irradiated surface 8 as illustrated in
In view of the above, the present invention provides an optical member capable of reducing illuminance unevenness or color unevenness which may cause an irradiated surface to look unattractive and eventually making the irradiated surface look nice, and an illumination apparatus using the optical member.
In accordance with one aspect of the present invention, there is provided an optical member for refracting light emitted from a light source and projecting the light from a light projecting surface thereof, including: a plurality of concave or convex portions formed on the light projecting surface, the concave or convex portions being concentrically arranged on a plurality of circles having a common center point, and the concave or convex portions on the circles adjoining to each other being arranged in different phase positions with respect to radial lines extending from the center point.
Preferably, the circles may be arranged at an equal interval.
The light source may be arranged at the opposite side of the optical member from the light projecting surface, the depth or height of the concave or convex portions growing larger as the position thereof gets closer to the light source.
It is preferred that the concave or convex portions may have center coordinates (x, y) arranged to satisfy equations (1) through (5):
(1) 0<Dn+1−Dn≦2·d, where d is the radius of the concave or convex portions seen in a plan view, n is the order of the circles counted from the center point, and Dn is the radius of the nth circle counted from the center point;
(2) 0<kn<2·Dn·π/d, where kn is the number of the concave or convex portions existing on the n-th circle counted from the center point (an integer);
(3) θn=360°/kn, where θn is the angle between the centers of the concave or convex portions adjoining to each other;
(4) x=Dn·cos(θn·Am+bn), where Am is an arithmetic progression in which a first term is 1, a common difference being 1 and the last term being kn, and bn is the phase of the center of each of the concave or convex portions; and
(5) y=Dn·sin(θn·Am+bn).
The concave or convex portions may have center coordinates (x, y) arranged to satisfy equations (6) through (8):
(6) θn=360°/(6·n), where n is the order of the circles counted from the center point, and On is the angle between the centers of the concave or convex portions adjoining to each other;
(7) x=√3d·n·cos(θn·km+bn), where d is the radius of the concave or convex portions seen in a plan view, bn is the phase of the center of each of the concave or convex portions (the phase conforming to one of the Fibonacci sequence, the Tribonacci sequence, the Tetranacci sequence, the Lucas sequence and the uniformly distributed random number), and km is an arithmetic progression in which a first term is 1, a common difference being 1 and the last term being 6·n; and
(8) y=√3d·n·sin(θn·km+bn).
In accordance with another aspect of the present invention, there is provided an illumination apparatus including the optical member described in the one aspect of the present invention.
With the optical member and the illumination apparatus in accordance with the present invention, the concave or convex portions formed on the light projecting surface are concentrically arranged on a plurality of circles having a common center point, the concave or convex portions on the circles adjoining to each other being arranged in different phase positions with respect to radial lines extending from the center point. Thanks to this feature, it is possible to refract the light passing through the optical member in a specified direction and to reduce generation of illuminance unevenness or color unevenness which may cause an irradiated surface to look unattractive.
Optical members and illumination apparatuses in accordance with embodiments of the present invention will now be described with reference to the accompanying drawings which form a part hereof.
Referring to
Used as the light source 2 is, e.g., a high-power white light emitting diode formed by combining a blue light emitting diode chip and a phosphor for converting the light of blue wavelength band having a peak wavelength of about 470 nm to the light of white wavelength band. As the phosphor combined with the blue light emitting diode chip to form the white light emitting diode, it is possible to use, e.g., a yellow phosphor, a combination of a yellow phosphor and a red phosphor or a combination of a green phosphor and a red phosphor. Examples of a phosphor material includes a YAG (yttrium-aluminum-garnet)-based material, a TAG (terbium-aluminum-garnet)-based material and a sialon-based material. The white light emitting diode is formed by mixing the phosphor with a resin material and covering the blue light emitting diode chip with the mixture.
The shape of a light emitting surface of the light source 2 is not particularly limited. For example, a plurality of packages composed of a light emitting diode chip and a phosphor material is two-dimensionally arranged on the substrate 3, e.g., a printed substrate (or a heat-radiating substrate). The light source 2 is not limited to the white light emitting diode but may be a small-size incandescent lamp or a small-size halogen lamp.
The substrate 3 is a general-purpose printed substrate. A substrate having superior dimensional stability and reduced deviation in warp and distortion is used as the substrate 3. For example, a glass epoxy substrate formed by superimposing glass clothes (fabrics) and impregnating the glass clothes with an epoxy resin is used as the material of the substrate 3. The substrate 3 is not particularly limited as long as it can be used at a required heat-resistant temperature. In order to efficiently dissipate the heat generated from the light source 2, heat sinks or radiator fins made of a material with good heat dissipation capability, e.g., copper, are attached to the backside of the substrate 3. A pedestal (not shown) is arranged on the substrate 3 to maintain the positional relationship between the light source 2 and the reflecting mirror 5, thereby obtaining light distribution as designed.
The optical member 4 is arranged on the light projecting surface of the illumination apparatus 1 independently of the reflecting mirror 5. The optical member 4 refracts the light emitted from the light source 2 in a desired direction and projects the light from the light projecting surface. A plurality of concave portions 4a (dimple-shaped depressions) having a circular shape when seen in a plan view is concentrically arranged on the light projecting surface of the optical member 4. The plan-view shape of the concave portions 4a is not limited to the circular shape but may be a polygonal shape or other shapes. While the concave portions 4a are taken as an example in the present embodiment, convex portions may be provided in place of the concave portions 4a.
The reflecting mirror 5 is an optical component of, e.g., semi-ellipsoid shape, for reflecting the light emitted from the light source 2 and projecting the light from the light projecting surface. The reflecting mirror 5 can be effectively used in case where the light emitting surface of the light source 2 is a perfect diffusion surface and the light emitted from the light source 2 is partially directed toward the substrate 3.
Next, description will be made on the arrangement of the concave portions 4a formed on the light projecting surface of the optical member 4 in accordance with the present embodiment.
As shown in
In the illumination apparatus 1 described above, the concave portions 4a formed on the light projecting surface of the optical member 4 are concentrically arranged on a plurality of circles having a common center point. The concave portions 4a on the circles adjoining to each other are arranged in different phase positions with respect to radial lines extending from the center point. Therefore, as compared with the conventional optical member 7 in which the concave portions 7a are arranged in a honeycomb pattern, the illuminance unevenness is reduced while the effect of reducing the color unevenness is kept. This makes it possible to improve the outward appearance of the irradiated surface 6. Since the circles on which the center coordinates of the concave portions 4a lie are arranged at an equal interval D, it is possible to facilitate the design of the optical member 4.
As shown in
A first modified example of the first embodiment will now be described with reference to
In the illumination apparatuses 1 in accordance with the present modified example, the depth of the concave portions 4a grows larger as the position thereof gets closer to the light source 2 and the height of the convex portions 4a′ grows larger as the position thereof gets closer to the light source 2. This makes it possible to increase the light diffusivity in the portion of the optical member 4 nearer to the light source 2 where illuminance unevenness or color unevenness is apt to occur. Further, it is possible to reduce the light diffusivity in the portion of the optical member 4 farther from the light source 2 where illuminance unevenness or color unevenness hardly occurs. As a result, it is possible to reduce generation of illuminance unevenness or color unevenness on an irradiated surface and to minimize reduction of the light emitting efficiency caused by the concave portions 4a or the convex portions 4a′.
An illumination apparatus in accordance with a second embodiment of the present invention will now be described with reference to
In the illumination apparatus 1 in accordance with the second embodiment, the center coordinates (x, y) of the concave or convex portions 4a or 4a′ is set to satisfy equations (1) through (5):
(1) 0<Dn+1−Dn≦2·d, where d is the radius of the concave or convex portions 4a or 4a′ seen in a plan view (see
(2) 0<kn<2·Dn·π/d, where kn is the number of the concave or convex portions existing on the n-th circle counted from the center point (an integer);
(3) θn=360°/kn, where en is the angle between the centers of the concave or convex portions adjoining to each other (see
(4) x=Dn·cos(θn·Am+bn), where Am is an arithmetic progression in which a first term is 1, a common difference being 1 and the last term being kn, and bn is the phase of the center of each of the concave or convex portions; and
(5) y=Dn·sin(θn·Am+bn).
In the illumination apparatus 1 of the second embodiment, the arrangement of the center coordinates of the concave or convex portions 4a or 4a′ can be easily calculated through the use of equations (1) through (5), which makes it possible to facilitate a design work. As in the first embodiment, the concave or convex portions 4a or 4a′ can be concentrically arranged on a plurality of circles having a common center point. The concave or convex portions 4a or 4a′ on the circles adjoining to each other can be arranged in different phase positions with respect to radial lines extending from the center point. It is therefore possible to reduce generation of illuminance unevenness.
An illumination apparatus in accordance with a third embodiment of the present invention will now be described with reference to
(6) θn=360°/(6·n), where n is the order of the circles counted from the center point (see
(7) x=√3d·n·cos(θn·km+bn), where d is the radius of the concave or convex portions seen in a plan view (see
(8) y=√3d·n·sin(θn·km+bn).
Now, description will be made on the Fibonacci sequence. The n-th Fibonacci number (Fn) is represented by equation (9):
(9) Fn+2=Fn+Fn+1 (n≧0), where F0 is 0 and F1 is 1.
The Fibonacci sequence is defined as a recurrence relation having two initial conditions, in which each term is equal to the sum of two preceding terms. For example, some of the first and following terms in the Fibonacci sequence are 0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55 and 89. The Fibonacci numbers often appear in the natural phenomena. For instance, it is not infrequent that the number of flower petals is the Fibonacci number. The phyllotaxy (the manner of attachment of leaves in a plant) is associated with the Fibonacci number.
Next, description will be made on the Tribonacci sequence. The n-th Tribonacci number (Fn) is represented by equation (10):
(10) Fn+3=Fn+Fn+1+Fn+2(n≧0), where F0 and F1 are 0 and F2 is 1.
In the Fibonacci sequence, each term is equal to the sum of two preceding terms. In contrast, each term is equal to the sum of three preceding terms in the Tribonacci sequence. For example, some of the first and following terms in the Tribonacci sequence are 0, 1, 1, 2, 4, 7, 13, 24, 44, 81, 149, 274 and 504.
Next, description will be made on the Tetranacci sequence. The n-th Tetranacci number (Fn) is represented by equation (11):
(11) Fn+4=Fn+Fn+1+Fn+2+Fn+3(n≧0), where F0, F1 and F2 are 0 and F3 is 1.
In the Tetranacci sequence, each term is equal to the sum of four preceding terms. For example, some of the first and following terms in the Tetranacci sequence are 0, 0, 0, 1, 1, 2, 4, 8, 15, 29, 56, 108, 208 and 401. The terms of a sequence obtained by replacing the first two terms of the Fibonacci sequence with 2 and 1 are called the Lucas sequence. The general term of the Lucas sequence is represented by equation (12):
(12) Ln=((1+√5)/2)n+((1−√5)/2)n.
The uniformly distributed random number stated above refers to a random number in which the appearance probabilities of all the values are equal to each other.
In the illumination apparatus 1 in accordance with the third embodiment, just like the second embodiment, the center coordinates of the concave or convex portions 4a or 4a′ are set based on equations (6) through (12). This makes it possible to reduce generation of illuminance unevenness and to facilitate a design work.
The present invention is not limited to the configurations of the foregoing embodiments but may be modified in many different forms without departing from the scope and spirit of the invention. For example, the optical member 4 may be applied to not only the illumination apparatus 1 but also other optical devices.
Number | Date | Country | Kind |
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2011-035738 | Feb 2011 | JP | national |