This application is based upon and claims the benefit of priority from prior Japanese Patent Application No. 2008-151098, filed Jun. 9, 2008, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to an illumination apparatus which is assumed to be used mainly outdoors, such as a street light, a garden light, or a projector. Further, the invention relates to a light source module using, for example, a plurality of light emitting diodes as a light source.
2. Description of the Related Art
An illumination apparatus for outdoors, such as a street light which illuminates a sidewalk and a roadway, is attached to a high point of a pole mounted at the side of a road. The illumination apparatus for outdoors of this kind uses, for example, a fluorescent lamp or an HID lamp as a light source. In recent years, to realize energy saving and easier maintenance, an attempt is being made to use a light emitting diode as the light source for outdoor illumination apparatuses in place of a fluorescent lamp or an HID lamp.
As regards a street light for increasing a crime prevention effect, for example, appropriate illumination intensity according to location is suggested so that the shape, the face shape, and the like of a person can be identified. Specifically, it is recommended to set a street light whose horizontal illuminance (average value) is 3 lux and whose vertical illuminance (minimum value) is 0.5 lux as the brightness at which the crime prevention effect can be expected. Concurrently, it is also requested to reduce the cost of mounting a street light and economically obtain light distribution of a wide range by widening the mounting interval of street lights as much as possible.
To satisfy the request, for example, in an illumination device for outdoors disclosed in Jpn. Pat. Appln. KOKAI Publication No. 2004-200102, a plurality of white light emitting diodes are used as a light source. This conventional illumination device for outdoors has a plurality of flat print boards on which the plurality of white light emitting diodes are mounted. The print board is attached to mounting hardware in an attitude such that the white light emitting diodes are directed downward and moreover in multiple directions.
However, a light emitting diode is a point source of light in which the shape of a light emitting part is small. Consequently, to obtain a luminous intensity distribution over a wide range by using light emitting diodes, a number of light emitting diodes have to be arranged. For this reason, a problem in cost occurs, the structure of the illumination device for outdoors is made more complex, and it cannot be avoided that the work of assembling the illumination device for outdoors becomes troublesome.
Therefore, if using a large number of light emitting diodes as a light source, how to arrive at an illumination device for outdoors which can distribute light over a wide range while simplifying the arrangement of light emitting diodes is an important issue.
Further, as regards a light emitting diode, despite the small shape of a light emitting part, the light intensity is high. Consequently, as disclosed in the Jpn. Pat. Appln. KOKAI publication, the light emitting part of the illumination device for outdoors using a number of light emitting diodes for illumination in multiple directions has a high brightness, which tends to produce glare to those looking at it.
An object of the present invention is to obtain a light source module which can distribute light over a wide range while simplifying the arrangement of light emitting elements, and which realizes reduced glare.
Another object of the present invention is to obtain an illumination apparatus having a light source module which can distribute light over a wide range while simplifying arrangement of light emitting elements and which realizes reduced glare.
To achieve the object, a light source module according to a first aspect of the present invention includes a reflector having a light reflection face, and a plurality of light emitting elements. The light reflection face is curved in a circular arc shape in a width direction of the reflector and extends in a longitudinal direction of the reflector. The light emitting elements are arranged in a center portion in the width direction of the light reflection face, and are arranged linearly along the longitudinal direction of the reflector.
In the first aspect of the invention, as the light emitting elements, light emitting diodes or a semiconductor laser using a semiconductor as a light generation source can be used. As the light emitting diode, a light emitting diode of an SMD (Surface Mount Device) type can be used. The number of the light emitting elements can be arbitrarily selected according to the luminous intensity distribution to be obtained. Although it is preferable for the plurality of light emitting elements to have the same function and the same performance, the functions and performances may be different from one another.
According to the first aspect of the invention, the light emitting elements arranged linearly are reflected in the light reflection face of the reflector. An image of the light emitting elements reflected in the light reflection face is expanded in association with the curvature of the light reflection face. As a result, the light emitting elements can be made to look larger, and the glare experienced when viewing the light emitting elements can be reduced.
In a second aspect of the invention, the light reflection face of the reflector has two reflection regions disposed symmetrically with the light emitting elements arranged linearly therebetween. Preferably, the light reflection face is finished as a mirror face. Light emitted from the light emitting elements toward the light reflection face is reflected by the two reflection regions to the outside of the reflector.
In a third aspect of the invention, the light source module further includes a module substrate on which the light emitting elements are mounted. The light emitting elements have an optical axis extending in a direction orthogonal to the module substrate. The reflection regions in the light reflection face reflect light from the light emitting elements toward the optical axis.
According to the third aspect of the invention, light emitted from the light emitting elements toward the light reflection face is reflected by the two reflection regions and, after that, emitted to the outside of the reflector along the optical axis. Consequently, the light emitted from the light emitting elements can be emitted effectively without wasting it.
To achieve the object, a light source module according to a fourth aspect of the invention has a module substrate, a plurality of light emitting elements, and a reflector. The light emitting elements are arranged linearly and mounted on the module substrate. The reflector includes: an opening extending in an arrangement direction of the light emitting elements and having a pair of peripheries facing each other with the light emitting elements therebetween; a first irradiation port facing the opening; a light reflection face extending from the peripheries of the opening so as to gradually expand toward the first irradiation port; a reflection wall disposed at one end along the arrangement direction of the light emitting elements so as to cross the light reflection face; and a second irradiation port facing the reflection wall at the other end along the arrangement direction of the light emitting elements.
In the fourth aspect of the invention, as the light emitting elements, light emitting diodes or a semiconductor laser using a semiconductor as a light generation source can be used. As the light emitting diode, a light emitting diode of an SMD (Surface Mount Device) type can be used. The number of the light emitting elements can be arbitrarily selected according to the light distribution to be obtained. Although it is preferable for the plurality of light emitting elements to have the same function and the same performance, the functions and performances may be different from one another.
The face facing the light emitting elements of the reflection wall may be flat, a curved face which curves so as to project toward the light emitting elements, or a curved face which is recessed with distance from the light emitting elements.
The light reflection face is, preferably, finished as a mirror face by forming, for example, a light reflection film made of a metal such as aluminum or silver on the surface of a mold made of a synthetic resin, thus constructing the reflector.
According to the fourth aspect of the invention, light emitted from the light emitting elements goes to the outside of the reflector via the first and second irradiation ports. Consequently, while preventing light leakage to a place where illumination is unnecessary, light can be emitted efficiently.
In a fifth aspect of the invention, the reflector is fixed on the module substrate, and the light emitting elements are exposed on the light reflection face via the opening in the reflector. Therefore, the module substrate and the reflector can be handled as a single assembly.
In a sixth aspect of the invention, the light reflection face has two reflection regions disposed symmetrically with the light emitting elements arranged linearly therebetween. The reflection regions are curved so that the light emitting elements reflected in the light reflection face appear larger, and the reflection wall has a flat face that continues to the reflection regions.
According to the sixth aspect of the invention, the light emitting elements are reflected in each of the two reflection regions, and an image of the reflected light emitting elements can be made look larger. Therefore, the glare experienced when viewing the light emitting elements can be further reduced.
In a seventh aspect of the invention, the light emitting elements arranged linearly are away from the focal point of the light reflection face. Consequently, light of the light emitting elements reflected by the light reflection face is expanded and emitted by the light reflector, and a luminous intensity distribution in a wide range can be obtained.
To achieve the object, an illumination apparatus according to an eighth aspect of the invention has an apparatus body, a frame, and a plurality of light source modules. The frame is supported by the apparatus body. The frame includes first and second attachment parts. The first and second attachment parts face each other tilted in opposite directions. The first and second attachment parts have attachment faces positioned on the side opposite to rear faces facing each other. A plurality of light source modules are arranged on the attachment face of the first attachment part and the attachment face of the second attachment part. Each of the light source modules includes: a module substrate fixed on each of the attachment faces; a plurality of light emitting elements mounted on the module substrate; and a reflector. The light emitting elements are arranged linearly in a direction crossing an arrangement direction of the light source modules. The reflector has: an opening extending in an arrangement direction of the light emitting elements and having a pair of peripheries facing each other with the light emitting elements therebetween; a first irradiation port facing the opening; a light reflection face extending from the peripheries of the opening so as to gradually expand toward the first irradiation port; a reflection wall disposed at one end along the arrangement direction of the light emitting elements so as to cross the light reflection face; and a second irradiation port facing the reflection wall at the other end along the arrangement direction of the light emitting elements.
The illumination apparatus according to the eighth aspect of the invention is assumed to be used as an illumination apparatus for outdoors such as a street light illuminating a road, a park, or the like. However, the present invention is not limited to this use. The illumination apparatus can be also used as an illumination apparatus for indoors mounted, for example, in a linearly extending place such as a corridor in a house, or an aisle.
In the case of using the illumination apparatus according to the eighth aspect of the invention as, for example, a street light, preferably, by emitting light obliquely downward from both sides sandwiching the linearly arranged light emitting elements, a luminous intensity distribution such that light reaches a wide range along the longitudinal direction of a road is obtained.
In the illumination apparatus according to the eighth aspect of the invention, by making the first and second irradiation ports of the reflector oriented downward, upward light from the light emitting elements can be reflected downward by the reflection wall. For this reason, light leakage to the sky is prevented, and an adverse influence on the natural environment and the living space can be prevented. Simultaneously, by efficiently guiding light to a place below the illumination apparatus where illumination is necessary, brightness in the place below the illumination apparatus can be assured.
In the illumination apparatus according to the eighth aspect of the invention, preferably, the apparatus body is made of a metal such as an aluminum die cast or a synthetic resin having a light blocking effect to block light traveling upward from the illumination apparatus. However, in a region around the illumination apparatus where brightness is high, as long as an adverse influence on the natural environment and living space does not occur, light leakage upward of the illumination apparatus is allowed.
The illumination apparatus according to the eighth aspect of the invention is mounted in an attitude in which the first and second irradiation ports of the reflector face downward, and the first and second attachment parts of the reflector tilt so as to become closer toward the second irradiation port. With such arrangement, the plurality of light emitting elements provided for each of the light source modules are just arranged linearly in a direction crossing the arrangement direction of the light source modules. Therefore, arrangement of the light emitting elements can be simplified.
Moreover, since each light source module has the light reflection face, distribution of light emitted by the light emitting element can be controlled by the light reflection face. In addition, the light source modules are disposed in the first and second attachment parts tilted in opposite directions. Consequently, light from the light source modules is emitted so as to expand as it travels to a place below the light source modules.
Further, the light reflection face expands toward the first irradiation port from the peripheries of the opening facing each other with the light emitting elements therebetween, so that the light emitting elements are reflected in the light reflection face and an image of the light emitting elements reflected in the light reflection face is made large. Therefore, the glare experienced when a person looks at the light emitting elements can be reduced.
In the eighth aspect of the invention, in the case of orienting the first and second irradiation ports of the reflector downward, the first and second attachment parts are disposed so as to be arranged in a V shape. The first and second attachment parts do not have to be disposed in a V shape but may be disposed so that the irradiation directions of light from the plurality of light source modules become symmetrical with respect to the frame as a center.
In a ninth aspect of the invention, the light reflection face has two reflection regions disposed symmetrically with the light emitting elements arranged linearly therebetween. The reflection regions are curved so that the light emitting elements reflected in the light reflection face appear larger, and the reflection wall has a flat face continuing to the reflection region.
According to the ninth aspect of the invention, the light emitting elements are reflected in each of the two reflection regions, and an image of the light emitting elements reflected can be made look larger. Therefore, the glare experienced when a person looks at the light emitting elements can be further reduced.
According to a tenth aspect of the invention, the illumination apparatus further includes a translucent cover supported by the apparatus body so as to cover the frame and the light source module. The translucent cover includes: a first light transmission part which covers a first irradiation port of a light source module arranged in the first attachment part; a second light transmission part which covers a second irradiation port of the light source module arranged in the first attachment part; a third light transmission part which covers a first irradiation port of the light source module arranged in the second attachment part; and a fourth light transmission part which covers a second irradiation port of the light source module arranged in the second attachment part.
In the tenth aspect of the invention, the translucent cover can be made of, for example, a synthetic resin material such as a transparent acrylic resin or polycarbonate, or a transparent glass. Further, the translucent cover may be made of, for example, a material of milky white color having a light diffusion property. In addition, the translucent cover may have, at least partly, a configuration for controlling light distribution, such as a prism. The configuration for controlling light distribution is not always necessary, and a function of controlling light distribution may be omitted from the translucent cover.
According to the tenth aspect of the invention, light emitted from the light source modules arranged in the first attachment part in the frame passes through the first and second light transmission parts in the translucent cover. Similarly, light emitted from the light source modules arranged in the second attachment part in the frame passes through the third and fourth light transmission parts in the translucent cover.
In an eleventh aspect of the invention, the first and third light transmission parts are disposed so as to be almost orthogonal to an emission direction of light emitted from the first irradiation port, and the second and fourth light transmission parts are disposed so as to be almost orthogonal to an emission direction of light emitted from the second irradiation port.
In the eleventh aspect of the invention, the sentence “the first to fourth light transmission parts are almost orthogonal to an emission direction of light” refers to the fact that reflection of light hardly occurs in the first to fourth light transmission parts when light passes through the first to fourth light transmission parts. Consequently, the first to fourth light transmission parts may be strictly orthogonal to the light emission direction geometrically, or not strictly orthogonal, and the crossing angle may be slightly deviated.
According to the eleventh aspect of the invention, light traveling from the light emitting elements toward the first to fourth light transmission parts is hardly reflected and passes through the first to fourth light transmission parts. Therefore, loss of light at the time of passing through the translucent cover is reduced, and the light can be efficiently emitted outside of the translucent cover.
In a twelfth aspect of the invention, a light intensity distribution along the arrangement direction of the light source modules when a vertical line is a reference is such that the total flux lies in a range of 0° to ±50° from the vertical line, the luminous flux distribution rate at 0° to less than ±20° from the vertical line is 50% to 60%, and the luminous flux distribution rate in the range of ±20° to ±50° from the vertical line is 40% to 50%.
According to the twelfth aspect of the invention, a surface to be illuminated which is positioned just below the illumination apparatus can be illuminated with a spot light of high intensity. Therefore, horizontal illuminance just below the illumination apparatus can be efficiently increased, and the brightness just below the illumination apparatus becomes sufficient. As a result, glare experienced when a person looks up at the illumination apparatus is reduced. For example, when the illumination apparatus is used as a street light, the glare rating, based on an index of glare, can be reduced.
In a thirteenth aspect of the invention, a light intensity distribution along a direction orthogonal to an arrangement direction of the light source modules when a vertical line is a reference is such that the luminous flux distribution rate at 0° to less than ±20° from the vertical line is 10% to 20%, the luminous flux distribution rate at ±20° to less than ±50° from the vertical line is 35% to 45%, the luminous flux distribution rate at ±50° to less than ±90° from the vertical line is 35% to 45%, and the luminous flux distribution rate at ±90° to less than ±180° from the vertical line is less than 5%.
According to the thirteenth aspect of the invention, for example, in the case of illuminating a road, light can be distributed so as to expand along the longitudinal direction of the road. Consequently, the road can be illuminated over a wide range, and horizontal illuminance can be increased by the distribution of light to a place just below the illumination apparatus. Therefore, the brightness just below the illumination apparatus becomes sufficient, and glare experienced when a person looks up at the illumination apparatus is reduced. Therefore, for example, in the case of using the illumination apparatus as a street light, the glare rating, based on an index of glare, can be set to 50 or less.
In addition, distribution of light upward of the illumination apparatus becomes less than 5%, and light leakage to the sky is prevented. Thus, an adverse influence on the natural environment and the living space can be reduced.
In a fourteenth aspect of the invention, the first and second light transmission parts are continued to each other, and the third and fourth light transmission parts are continued to each other.
According to the fourteenth aspect of the invention, by the light emitted from the light emitting elements, four parts of the translucent cover can be made to shine. Consequently, sufficient light can be led to places needing illumination and the appearance of the illumination apparatus which is turned on is characteristic.
In a fifteenth aspect of the invention, the reflector of each of the light source modules has a plurality of fixing parts overlapping the first and second attachment parts of the frame. The fixing parts are projected from the reflector along a direction orthogonal to the arrangement direction of the light source modules.
According to the fifteenth aspect of the invention, the fixing part is not interposed between neighboring light source modules, so that the interval between the neighboring light source modules can be narrowed. Thus, the illumination apparatus can be formed more compactly.
Moreover, a plurality of light source modules are integrally continued without being interrupted in the arrangement direction. Consequently, the plurality of light source modules can be made to appear as a linear light source extending in the arrangement direction.
In a sixteenth aspect of the invention, the reflector has a width along the arrangement direction of the light source modules, and the fixing parts are positioned in a range of the width of the reflector.
According to the sixteenth aspect of the invention, the plurality of light source modules can be arranged without intervals. Thus, wasted space can be eliminated from the light source modules, which is advantageous in making the illumination apparatus more compact.
In a seventeenth aspect of the invention, the module substrate of the light source module has an outer periphery sandwiched between the frame and the reflector, and a plurality of engagement parts formed in the outer periphery. The reflector has a plurality of projections which engage with the engagement parts, thereby determining relative positions between the reflector and the module substrate, and a plurality of retaining nails which retain the outer periphery of the module substrate, thereby holding the module substrate in the reflector.
According to the seventeenth aspect of the invention, a plurality of light emitting elements arranged linearly can be assembled in appropriate positions in the light reflection face of the reflector with high precision. Simultaneously, the module substrate and the reflector in an assembled state can be attached to the frame. Therefore, the work of assembling the illumination apparatus can be performed easily.
In addition, the light emitting elements are disposed in the opening in the reflector and exposed on the light reflection face. Consequently, for example, even when heat is generated during light-on of the light emitting elements, i.e., the light emitting diodes, dissipation of heat from the light emitting elements is not disturbed by the reflector. In particular, if the first and second irradiation ports of the reflector are directly open to the atmosphere, heat of the light emitting elements can be dissipated from the first and second irradiation ports to the atmosphere. Therefore, heat of the light emitting elements tends not to build up on the inside of the light reflection face, which is preferable from the viewpoint of suppressing a temperature rise in the light emitting element.
In an eighteenth aspect of the invention, the frame and the reflector are made of a metal, and the light emitting elements are thermally connected to the frame and the reflector via the module substrate.
According to the eighteenth aspect of the invention, for example, in the case where the light emitting elements are light emitting diodes accompanying heat generation during light-on, the heat of the light emitting diodes can be transmitted from the module substrate to the frame and the reflector. Thus, the frame and the reflector can be utilized as a heat sink that helps dissipate heat from the light emitting diodes.
Additional objects and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objects and advantages of the invention may be realized and obtained by means of the instrumentalities and combinations particularly pointed out hereinafter.
The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention, and together with the general description given above and the detailed description of the embodiments given below, serve to explain the principles of the invention.
A first embodiment of the present invention will be described below with reference to
As shown in
As shown in
The linear module is assembled to the reflector 14. The reflector 14 is formed by, for example, a plate member of stainless steel or aluminum. As shown in
The linear module is disposed on the light reflection face 14a of the reflector 14. In other words, the module substrate 11a as a component of the linear module is within the reflector 14 and is positioned in the center portion along the width direction of the reflector 14. Further, the module substrate 11a is placed on the light reflection face 14a so as to extend in the center line Y-Y direction, which is the longitudinal direction of the reflector 14. Both ends in the longitudinal direction of the module substrate 11a are fixed to the reflector 14 by fixing means such as screws.
In such a manner, the LEDs 11 are positioned on the light reflection face 14a along the center line Y-Y of the reflector 14. As a result, the light reflection face 14a is divided into two reflection regions 14b and 14c sandwiching the linear module. The reflection regions 14b and 14c are disposed symmetrically with the LEDs 11 arranged linearly as a border.
Therefore, as shown in
The apparatus body 15 is, for example, an elongated box made by an aluminum die cast. The apparatus body 15 has an opening 15a which opens downward. As shown in
The first receptacle 15b houses the frame 17. The second receptacle 15c houses a lighting device 20 for controlling the light source modules 12. The frame 17 is provided to support the ten light source modules 12 and is constructed of, for example, a plate member of stainless steel or aluminum. The frame 17 is supported at the bottom of the apparatus body 15 so as to be positioned on the center line Z-Z in the longitudinal direction of the apparatus body 15.
As shown in
Concretely, the first and second attachment parts 17a and 17b are disposed tilted so as to be apart from each other toward the apparatus body 15 and symmetrically with respect to the center line Z-Z in the longitudinal direction of the apparatus body 15. Consequently, when the frame 17 is viewed from the longitudinal direction of the apparatus body 15, the first and second attachment parts 17a and 17b are disposed in a V shape at a predetermined angle α. In such a manner, the frame 17 is tapered downward of the apparatus body 15. The lower end of the first attachment part 17a and the lower end of the second attachment part 17b form a ridge 17c of the frame 17 in cooperation with each other.
Further, the first and second attachment parts 17a and 17b have rear faces 17d and attachment faces 17e. The rear face 17d of the first attachment part 17a and the rear face 17d of the second attachment part 17b face each other. The attachment faces 17e are positioned on the side opposite to the rear faces 17d and are exposed to the outside of the frame 17. In the embodiment, for example, a mirror-like finish is performed on the attachment faces 17e of the first and second attachment parts 17a and 17b. As a result, the frame 17 also has a function as a light reflecting member.
As shown in
In other words, the light source modules 12 are arranged at intervals in the direction almost orthogonal to the arrangement direction of the LEDs 11. The intervals between the neighboring light source modules 12 are preferably equal intervals. The light source modules 12 are fixed to the frame 17 by, for example, spot-welding the center portion in the width direction of the reflector 14 to the attachment faces 17e of the first and second attachment parts 17a and 17b.
In such a manner, the ten light source modules 12 are disposed so as to be symmetrical around the center line Z-Z in the longitudinal direction of the apparatus body 15. The linear module specified by the LEDs 11 and the reflectors 14 extend straight in the vertical direction when the street light 10 is seen from a side as shown in
As shown best in
Consequently, as shown by an arrow in
The translucent cover 13 is used to control the light emitted from the LEDs 11 of the light source modules 12 and is made of a synthetic resin material such as transparent acrylic resin. The translucent cover 13 is an elongated box having a size corresponding to the apparatus body 15. The translucent cover 13 has an opening 13a which opens upward, a pair of side faces 13b and 13c, and a front end face 13d. The opening 13a has a size matching the opening 15a of the apparatus body 15. The side faces 13b and 13c extend in the longitudinal direction of the translucent cover 13. The front end face 13d is provided across the side faces 13b and 13c in a position corresponding to the first receptacle 15b. Further, the side faces 13b and 13c are tilted so as to be closer to each other in the downward direction. The lower ends of the side faces 13b and 13c cooperatively form a bottom part 13e which is tapered and peaked. Consequently, the translucent cover 13 has a V-shaped section and is widened toward the opening 13a.
The opening 13a in the translucent cover 13 fits the opening 15a in the apparatus body 15. By such fitment, the frame 17, the light source modules 12, and the lighting device 20 are covered with the translucent cover 13. For example, a packing (not shown) made of a silicon resin is interposed between the opening 13a in the translucent cover 13 and the opening 15a in the apparatus body 15. By use of the packing, a waterproof property of the street light 10 is assured.
Further, the translucent cover 13 is fixed to the apparatus body 15 via not-shown screws. Consequently, by unfixing the screws of the translucence cover 13 to detach the translucent cover 13 from the apparatus body 15, maintenance work on the light source modules 12 and the lighting device 20 can be executed.
As shown in
On the inner face of the translucent cover 13, a plurality of prisms 13f are integrally formed. The prisms 13f are provided to obtain a luminous intensity distribution over a wide range by refracting light of the LED 11 having high directivity. The apex angle of the prism 13f is about 90°, and the prism 13f has a ridge line passing the apex of the apex angle. The ridge line extends in a direction almost orthogonal to the arrangement direction of the LEDs 11 of the light source modules 12 and is continued to the side faces 13b and 13c and the front end face 13d of the translucent cover 13. In other words, the ridge lines of the plurality of prisms 13f are arranged at predetermined intervals in the direction of the center line X-X of the light source module 12 matching the arrangement direction of the LEDs 11.
In the street light 10 of the embodiment, length L1 of the apparatus body 15 shown in
As shown in
Next, the action when the street light 10 is attached to the pole P and used will be described.
As shown in
Further, the first and second attachment parts 17a and 17b of the frame 17 extend almost horizontally in a direction intersecting the road A and tilt so as to be apart from each other toward the apparatus body 15 which is positioned above. Consequently, the attachment faces 17e of the first and second attachment parts 17a and 17b are directed obliquely downward of the apparatus body 15 so as to be symmetrical with respect to the vertical line passing through the center of the apparatus body 15. As a result, the five light source modules 12 supported by the first attachment part 17a and the five light source modules 12 supported by the second attachment part 17b are also disposed symmetrically with respect to the vertical line passing through the center of the apparatus body 15.
Light emitted from the LED 11 to both sides of the optical axis O-O as a center are reflected by the reflection regions 14b and 14c in the reflector 14 and their emission directions are changed downward so as to follow the optical axis O-O. Further, the light traveling downward of the reflector 14 is refracted by the prism 13f in the translucent cover 13, and its emission direction is diffused. As a result, the light beams emitted from the light source module 12, as shown by the arrow in
On the other hand, light emitted from the LEDs 11 of the light source modules 12 downward of the optical axis O-O as shown in
As a result, since the light diffused by the prism 13f travels downward from the street light 10, the area just below the street light 10 can be illuminated with a soft light. In addition, when a person looks up at the street light 10, he/she is not dazzled. Therefore, a luminous intensity distribution which is safe for eyes can be obtained.
The LEDs 11 assembled in the reflector 14 are disposed in the center portion in the width direction of the light reflection face 14a on the inside of the light reflection face 14a which curves in a circular arc shape. With this arrangement, the line of the LEDs 11 arranged linearly is reflected in each of the two reflection regions 14b and 14c in the light reflection face 14a. Each of the images of the LEDs 11 reflected in the reflection regions 14b and 14c is expanded and larger than the size of the actual LED 11. That is, the existence of the light reflection face 14a makes it appear as if there are more LEDs 11 than there actually are, and makes each of the LEDs 11 look larger. Therefore, although each of the LEDs 11 is a point light source of high brightness, glare can be reduced.
In the light source module 12 of the embodiment, the distances from the LEDs 11 arranged linearly to the reflection regions 14b and 14c in the light reflection face 14a are maintained uniformly. Consequently, reflection of the light reflection face 14a with respect to each of the LEDs 11 is controlled equally. Therefore, while widening the light from the LEDs 11 arranged linearly in the width direction of the road A, the light can be led to a far place along the longitudinal direction of the road A. With this arrangement, as schematically shown in
In the street light 10 as the first embodiment of the present invention, the plurality of LEDs 11 are disposed linearly along the center line X-X of the light source module 12. Consequently, the structure of the light source module 12 is simplified and assembling work is also simple.
Further, in the first embodiment, light of the LED 11 having high directivity is refracted by the prism 13f having the ridge line extending in the direction almost orthogonal to the arrangement direction of the LEDs 11, thereby obtaining the luminous intensity distribution over a wide range. Therefore, as compared with the conventional technique using a number of expensive LEDs to obtain the luminous intensity distribution over a wide range, the problem in cost can be solved.
Further, each of the light source modules 12 has a linear module obtained by combining the LEDs 11 arranged linearly and the reflector 14. Consequently, by selecting some light source modules 12 to be turned on from the linear modules, lighting having an appropriate light intensity distribution according to the place where the street light 10 is mounted can be performed.
Concretely, for example, in the case of illuminating the end of a dead-end road, out of the five light source modules 12 attached to the first attachment part 17a or the five light source modules 12 attached to the second attachment part 17b, the light source modules 12 positioned on the side of the dead end are omitted or maintained so as not to be turned on. With this arrangement, light leakage in the direction where lighting is unnecessary is prevented, and the influence on the living space of the neighborhood and natural environment can be reduced. Therefore, the street light 10 providing an appropriate luminous intensity distribution according to a place and having excellent general versatility can be provided.
It is also possible to add a light control apparatus to the lighting device 20, select some light source modules 12 from the plurality of light source modules 12, and turn on or off the selected light source modules 12. With this arrangement, lighting for the purpose of crime prevention according to the circumstances of a place where the street light 10 is mounted such as buildings and environments around a road can be performed.
In the first embodiment of the present invention, as each of the LEDs 11, a high-brightness high-output LED of the SMD type which obtains white light by a yellow phosphor excited by a blue LED chip is used. An LED of the SMD type is constructed as a linear module having general versatility in cooperation with the module substrate 11a. White light emitted from the LED of the SMD type is controlled by the prism 13f so that the desired luminous intensity distribution can be obtained at the time of passing through the translucent cover 13. Consequently, it is unnecessary to control the luminous intensity distribution in each of a plurality of shell-type LEDs as disclosed in the above-described Jpn. Pat. Appln. KOKAI Publication, thus the present invention is more advantageous also from the viewpoint of cost.
In the first embodiment of the present invention, each of the light source modules 12 has a reflector 14. With this configuration, light emitted from the LED 11 in a direction different from the optical axis O-O can be reflected by the reflection regions 14b and 14c in the reflector 14 in a direction along the optical axis O-O. Concurrently, in the first embodiment, the auxiliary reflector 17f is added to the frame 17 supporting the reflector 14. The auxiliary reflector 17f reflects light emitted upward from the LED 11 toward the translucent cover 13. As a result, light emitted from the LED 11 in each of the light source modules 12 can be effectively utilized, and a street light 10 providing an appropriate luminous intensity distribution can be obtained.
In addition, a long-life LED 11 is used as a light emitting element, so that the frequency of maintenance such as lamp replacement can be reduced. Thus, while reducing the maintenance cost of the street light 10, the street light 10 can be used for a long time.
Further, by covering the plurality of LEDs 11 with the translucent cover 13 in which the prisms 13f are formed, lighting for the purpose of crime prevention which provides the luminous intensity distribution over a wide range of the road A can be realized. Therefore, the mounting interval of the street lights 10 can be widened, so that lighting for the purpose of crime prevention can be realized economically.
The LED 11 does not require a heavy, large stabilizer required by a fluorescent lamp and an HID lamp. Therefore, miniaturization and lighter weight of the street lamp 10 can be realized. For this reason, the work of mounting the street light 10 in a high place on the pole P can be performed easily, and the street light 10 can be mounted to the pole P reliably.
Five light source modules 12 are disposed in each of the first and second attachment parts 17a and 17b which are disposed in a V shape. The first and second attachment parts 17a and 17b are disposed symmetrically with respect to the center line Z-Z of the apparatus body 15. With this configuration, light emitted from the light source modules 12 can be reliably controlled so that the emission directions become symmetrical, so that a stable luminous intensity distribution can be obtained.
The plurality of light source modules 12 are supported by the frame 17 and housed in a lump in the first receptacle 15b in the apparatus body 15. Simultaneously, the lighting device 20 for turning on the light source modules 12 is housed in the second receptacle 15c in the apparatus body 15. Consequently, arrangement of the parts in the apparatus body 15 is simplified, and a street light 10 which is easily assembled can be obtained.
The apex angle of the prism 13f in the translucent cover 13 can be appropriately set in accordance with the positional relation with the light source module 12 and the luminous intensity distribution to be obtained. Consequently, the apex angle of the prism 13b is not limited to about 90° as described in the first embodiment.
In the first embodiment, the reflector 14, the frame 17, and the auxiliary reflector 17f are subjected to mirror-like finishing. However, in the case where the reflector 14 and the frame 17 are made of a shiny metal such as stainless steel or aluminum, the mirror-like finishing need not be performed.
Further, the reflector may be formed of a white synthetic resin material such as PBT (polybutylene terephthalate). In the case where the reflector is made of a synthetic resin, a mirror finish process or half-mirror finish process may be performed on the reflector.
In the first embodiment, all of the light source modules have reflectors. However, the present invention is not limited to this configuration. The desired luminous intensity distribution may be obtained by providing reflectors for a part of the light source modules.
The reflector may be formed integrally with another part such as an apparatus body or a module substrate. Although a plurality of reflectors are made of the same material and have the same reflection performance in the first embodiment, the present invention is not limited to the embodiment. For example, reflectors of neighboring light source modules may be formed of different materials, or the reflection performances of the reflectors of neighboring light source modules may be made different from each other. In addition, reflectors of neighboring light source modules may be integrated with each other.
In the first embodiment, the lighting device is housed in the apparatus body. However, the present invention is not limited to this arrangement. For example, the lighting device may be separated from the apparatus body and mounted in another place.
Simultaneously, the translucent cover may not be fixed to the apparatus body by screws. For example, one end of the translucent cover may be coupled to an opening in the apparatus body via a hinge. With this configuration, the translucent cover can swing between a closed position in which the translucent cover covers the opening in the apparatus body and an open position in which the translucent cover opens the opening in the apparatus body. Consequently, it is unnecessary to detach the translucent cover from the apparatus body at the time of performing maintenance on the lighting device and the light source modules. Therefore, the work required by the maintenance on the lighting device and the light source modules can be performed easily.
The light emitting element is not limited to an LED semiconductor light emitting element. In place of an LED, another light source such as a cold-cathode lamp, a halogen lamp, or an EL (electroluminescence) may be used.
In the first embodiment, the street light is supported in the upper part of the pole so that the ridge lines of prisms in the translucent cover extend in the direction crossing the road. However, the ridge lines of the prisms do not have to strictly extend in the direction crossing the road geometrically. For example, the ridge lines of the prisms may extend at an angle slightly deviated in the longitudinal direction of a road from the direction crossing the road in accordance with circumstances of the place where the street light is to be mounted.
In the first embodiment, the prisms 13f are continuously formed in the entire side faces 13b and 13c of the translucent cover 13. In contrast, in the second embodiment, the prisms 13f are formed only in a plurality of places facing the light source modules 12 in the side faces 13b and 13c of the translucent cover 13. Desirably, by performing a transparent or light diffusing process, a part where no prisms 13f exist in the side faces 13b and 13c of the translucent cover 13 can be made semitransparent.
With this configuration, light of the LEDs 11 having strong directivity passes through the transparent part 13g in the translucent cover 13 and is emitted to the outside of the translucent cover 11. Consequently, light of the LEDs 11 passes through the translucent cover 13 without being largely diffused, and light reaches a further place.
On the other hand, light of the LEDs 11 traveling straight down from the street light 10 is diffused by the prisms 13f positioned in the bottom part 13e of the translucent cover 13. As a result, since the light diffused by the prisms 13f travels down from the street light 10, the area just below the street light 10 can be illuminated with soft light. In addition, when a person looks up at the street light 10, he/she is not dazzled. Therefore, a luminous intensity distribution which is safe to the eyes can be obtained.
Further, by appropriately setting the apex angle of the prism 13f positioned on the upper side of the transparent part 13g of the translucent cover 13, light passing through the upper part in the translucent cover 13 can be refracted downward. Therefore, light leakage from the street light 10 upwards is prevented, and any influence on the living space of a neighborhood and natural environment can be reduced.
With such a configuration, light of the LEDs 11 traveling to the area just below the street light 10 passes through the transparent part 13h in the translucent cover 13, so that diffusion of light is suppressed. Consequently, a spot just below the street light 10 can be illuminated, and illuminance just below the street light 10 can be sufficiently assured.
As shown in
As a result, a luminous intensity distribution of the street light 10 can be adjusted according to a place and, for example, the luminous intensity distribution suitable for a curved road or a corner of a road can be obtained.
As shown in
Mounting intervals between outdoor illumination apparatuses such as street lights are required to be increased to realize energy saving and simplification of construction. To illuminate a road with appropriate brightness while satisfying such requirement, each street light has to have a luminous intensity distribution such that light extends along the longitudinal direction of a road.
However, in the case where a street light having a luminous intensity distribution such that light extends along the longitudinal direction of a road is mounted, for example, at a corner of a road or a curved road, a residual part of the light may travel off the road. Such residual light is leaked light, which may travel to a part where illumination is unnecessary, and may exert an adverse influence on the living space in a neighborhood and the natural environment.
A seventh embodiment of the present invention discloses a configuration of a street light which can illuminate a corner of a road and a curved road with appropriate brightness while preventing light leakage to a part where illumination is unnecessary.
With reference to
As shown in
The prism 13f has a ridge line passing through the apex of the apex angle. The ridge line extends in a direction almost orthogonal to the arrangement direction of the plurality of LEDs of each of the light source modules 12. A side plate 40a extending downward is formed integrally with the apparatus body 15. The side plate 40a faces the rear face 17d of the first attachment part 17a and closes an open end of the translucent cover 13. Between the translucent cover 13 and the side plate 40a, a packing (not shown) for assuring a waterproof property is interposed.
As shown in
The prism 13f has a ridge line passing through the apex of the apex angle. The ridge line extends in a direction almost orthogonal to the arrangement direction of the plurality of LEDs of each of the light source modules 12. A side plate 40b extending downward is formed integrally with the apparatus body 15. The side plate 40b faces the rear face 17d of the second attachment part 17b and closes an open end of the translucent cover 13. Between the translucent cover 13 and the side plate 40b, a packing (not shown) for assuring a waterproof property is interposed.
When the light source modules 12 of the first street light R are turned on, light emitted from the LEDs of the light source modules 12 passes through the translucent cover 13. The light passed through the translucent cover 13 is diffused by the prisms 13f. The light diffused by the prisms 13f is emitted obliquely downward from the translucent cover 13 so as to be away from the side plate 40a of the apparatus body 15.
Similarly, when the light source modules 12 of the second street light L are turned on, light emitted from the LEDs of the light source modules 12 passes through the translucent cover 13. The light passed through the translucent cover 13 is diffused by the prisms 13f. The light diffused by the prisms 13f is emitted obliquely downward from the translucent cover 13 so as to be away from the side plate 40b of the apparatus body 15.
Each of the first and second street lights R and L is attached to the upper part of the pole via the support member and the attachment band. In the seventh embodiment, preferably, the support member is swingable about the pole so that the first and second street lights R and L can be mounted in arbitrary positions in the circumferential direction of the pole.
In other words, the first and second street lights R and L are attached to the pole P in an attitude such that the translucent covers 13 are directed to the surface of the road A and the plurality of light source modules 12 are arranged in the direction crossing the road A. With this configuration, in a manner similar to the first embodiment, the ridge lines of the prisms 13f in the translucent cover 13 extend in the direction crossing the road A.
When the first and second street lights R and L are turned on, light from the light source modules 12 are emitted toward the road surface so as to be symmetrical with each other along the longitudinal direction of the road A. Consequently, as schematically shown in
The prisms 13f in the translucent cover 13 control the light transmitting through the translucent cover 13 so that the light does not reach a place other than the road A.
As shown in
When the first street light R is turned on, light from the light source modules 12 is emitted to the region below the first street light R toward the road A curved on the right side of the pole P. When the second street light L is turned on, light from the light source modules 12 is emitted to the region below the second street light L toward the road A curved on the left side of the pole P. As a result, as schematically shown in
Therefore, light emitted from the first and second street lights R and L can be prevented from being leaked to the region outside of the road A as shown by broken lines in
As shown in
When the first street light R is turned on, light from the light source modules 12 is emitted to the region below the first street light R toward the linear part A1 of the road A. When the second street light L is turned on, light from the light source modules 12 is emitted to the region below the second street light L toward the other linear part A2 of the road A. As a result, as schematically shown in
On the other hand, in the example shown in
When the second street light L is turned on, light diffused by the prisms 13f is emitted to the road surface in the longitudinal direction of the road A from the terminating end of the road A. As a result, as schematically shown in
When the pole P is mounted on the left side part of the road A at the time of illuminating the terminating end of the road A, the first street light R is used. The first street light R is attached to the pole P in an attitude in which the side plate 40a is directed to the terminating end of the road A and the translucent cover 13 crosses the road A. With this arrangement, a luminous intensity distribution similar to that in the case of using the second street light L can be obtained.
In the seventh embodiment, appropriate illumination according to the shape of the road A is enabled, and light leakage to a region which does not require illumination can be minimized. Further, the first and second street lights R and L having high general versatility which can easily meet conditions of a place to be illuminated can be provided.
In addition, in the seventh embodiment, it is sufficient for each of the first and second street lights R and L to emit light in one direction. Consequently, as compared mainly with the first embodiment, the number of light source modules 12 can be reduced, and the cost can be reduced. Simultaneously, the shape of each of the reflector 14 and the translucent cover 13 can be made smaller, and miniaturization and reduced weight of the first and second street lights R and L can be realized. Therefore, the work of attaching the first and second street lights R and L to the pole P can be easily performed.
In the seventh embodiment, light is diffused by the translucent cover having the prisms. The present invention is not limited to the seventh embodiment. For example, light may be diffused by a lens member such as a convex lens. Consequently, an optical system can be constructed by combination of the light source modules and lens members, or combination of the light source modules, the reflector, and the lens members.
In the eighth embodiment, the apparatus body 15 is made by, for example, die-cast aluminum. The frame 17 fixed to the inner face of the apparatus body 15 is made of, for example, a metal having excellent thermal conductivity such as aluminum.
As shown in
As shown in
As shown in
Each of the reflectors 14 has a body made of a synthetic resin such as PBT or ABS. Aluminum or silver is vapor-deposited on the surface of the body. Aluminum or silver is vapor-deposited in a range of dimension E1 in
Each reflector 14 has the light reflection face 14a extending in its longitudinal direction. The light refection face 14a is made of aluminum or silver which is vapor-deposited on the body. With this configuration, the light reflection face 14a serves as a mirror face.
As shown in
The first irradiation port 52 faces the opening 51 and is continued to the light reflection face 14a. The reflection region 14b in the light reflection face 14a extends from one of the edges of the opening 51 toward the first irradiation port 52. The reflection region 14c in the light reflection face 14a extends from the other edge of the opening 51 toward the first irradiation port 52. The reflection regions 14b and 14c are curved in a circular arc shape so as to be apart from each other with a distance from the opening 51 toward the first irradiation port 52. Consequently, the light reflection face 14a gradually expands from the opening 51 toward the first irradiation port 52.
As shown in
The second irradiation port 53 is positioned at the lower end in the longitudinal direction of the reflector 14. The second irradiation port 53 is continued to the first irradiation port 52 and the light reflection face 14a.
As shown in
When the reflector 14 is seen from the front as shown in
Each reflector 14 has a first fixing part 55 and a second fixing part 56. The first fixing part 55 is integrally projected upward from the upper end of the reflector 14. The second fixing part 56 is integrally projected downward from the lower end of the reflector 14. The first and second fixing parts 55 and 56 are positioned in the range of the width of the reflector 14.
As shown in
As shown in
Further, a pair of retaining nails 59 are integrally formed on the rear face of the reflector 14. The retaining nails 59 are positioned between the engagement projections 58 and are projected from the rear face of the reflector 14. Each of the retaining nails 59 has a base continued to the reflector 14 and can be elastically deformed about its base as a fulcrum.
The module substrate 11a has an electric insulation plate, a plurality of wiring patterns, and copper foil. The electric insulation plate has a size almost the same as that of the rear face of the reflector 14. The wiring patterns are provided to connect the plurality of LEDs 11 in series and are formed on the surface of the electric insulation plate. The copper foil is an example of a heat spreader and continuously covers the surface and rear face of the electric insulation plate. The copper foil is electrically insulated from the wiring patterns.
As shown in
The nail receiving grooves 22 are notched so as to be open at the right and left side edges of the module substrate 11a. The nail receiving groove 22 is positioned in a center portion in the longitudinal direction of the module substrate 11a. In the embodiment, the nail receiving grooves 22 are not essential components and need not be provided.
The module substrate 11a is held on the rear face of the reflector 14 by making the engagement parts 21 engage with the engagement projections 58 of the reflector 14 and retaining the retaining nails 59 of the reflector 14 by the nail receiving grooves 22. In such a manner, the reflector 14 and the module substrate 11a are stacked in a state where they are positioned. As a result, at the time of attaching the light source modules 12 to the first and second attachment parts 17a and 17b of the frame 17, the reflector 14 and the module substrate 11a can be handled as a single assembly. Consequently, the troublesome work of attaching each of the reflector 14 and the module substrate 11a individually to the frame 17 is unnecessary.
Further, the nail receiving grooves 22 by which the retaining nails 59 are retained are notched so as to be open at the side edges of the module substrate 11a. Consequently, the retaining nails 59 do not protrude in the width direction of the reflector 14, and the narrow reflector 14 can be formed.
As shown in
At the time of mounting the LEDs 11 on the module substrate 11a, heat dissipating means (not shown) may be provided for the LED 11. In the LED 11, the temperature tends to rise in the anode 11c more easily than in the cathode 11d. Consequently, by making the anode 11c of one of neighboring LEDs 11 on the mount surface of the module substrate 11a face the cathode 11d of the other LED 11 on the mount surface, the temperature distribution of the module substrate 11a can be made uniform. Therefore, variations in the temperature among the plurality of LEDs 11 can be suppressed.
As shown in
When the module substrate 11a is stacked on the reflector 14, the LEDs 11 enter the opening 51 in the reflector 14 and are exposed in the center portion of the light reflection face 14a. As a result, the plurality of LEDs 11 arranged linearly are positioned in the center portion in the width direction of the light reflection face 14a so that the plurality of LEDs 11 are reflected in the two reflection regions 14b and 14c in the light reflection face 14a.
In other words, the two reflection regions 14b and 14c in the light reflection face 14a are disposed symmetrically with each other using the column of the LEDs 11 as a border. With this arrangement, the distance between each of the LEDs 11 and the reflection region 14b and that between each of the LEDs 11 and the other reflection region 14c are equal. Therefore, light emitted from the plurality of LEDs 11 arranged linearly is uniformly reflected by the light reflection face 14a. Thus, illumination in a predetermined range along the extension direction of the road is made possible while extending light to the entire width of the road.
On the other hand, the reflection wall 54 in the reflector 14 is positioned at the upper end along the arrangement direction of the LEDs 11. Consequently, the distances between the LEDs 11 linearly arranged and the reflection wall 54 are different from each other. The under face of the reflection wall 54 downwardly reflects mainly light emitted from the LED 11 closest to the reflection wall 54.
As shown in
The LEDs 11 mounted on the module substrate 11a are disposed in the opening 51 in the reflector 14. The peripheries of the opening 51 face each other with the LEDs 11 therebetween. For this reason, when the light source module 12 is seen from the front, as shown in
The LED 11 generates heat when it is on. The heat of the LED 11 is transmitted to the anode 11c and the cathode 11d close to the LED 11 and solder connecting the electrodes and the wiring patterns. The anode 11c and the cathode 11d of each LED 11 are exposed on the inside of the reflector 14. Consequently, the heat of the LED 11 transmitted to the anode 11c, the cathode 11d, and the solder can be dissipated to the atmosphere without being disturbed by the reflector 14. By such heat dissipation, a temperature rise of the LED 11 is suppressed, and deterioration in the luminous efficacy and the life of the LED 11 can be suppressed.
Moreover, the LEDs 11 are arranged linearly on the inside of the opening 51, so that a slit-shaped gap is formed between each LED 11 and the periphery of the opening 51. Due to the current of air passing through the gap, heat retention around the LEDs 11 is suppressed, and heat dissipation of the LEDs 11 is accelerated. As a result, occurrence of a temperature difference among the plurality of LEDs 11 is prevented, and variations in emission colors of the LEDs 11 can be suppressed.
In the eighth embodiment, to accelerate heat dissipation of the LEDs 11, the anodes 11c, the cathodes 11d, and the soldered parts between the electrodes and the wiring patterns are exposed on the inside of the reflector 14.
However, the present invention is not limited to the above configuration. For example, the anode 11c or the cathode 11d may be covered with the reflector 14. Further, the soldered part between the anode 11c and the wiring pattern or the soldered part between the cathode 11d and the wiring pattern may be covered with the reflector 14. In such a case as well, the heat dissipation performance of the LED 11 is increased, and deterioration in the luminous efficacy of the LED 11 can be suppressed.
In short, by making at least one of the anode 11c and the cathode 11d exposed on the inside of the reflector 14, the heat of the LED 11 can be dissipated via the module substrate 11a. Therefore, deterioration in the luminous efficacy of the LED 11 can be suppressed, and a high-performance street light 10 can be obtained.
The light source modules 12 are fixed on the attachment faces 17e of the first and second attachment parts 17a and 17b of the frame 17 in the longitudinal direction of the first and second attachment parts 17a and 17b. Each of the light source modules 12 is fixed by making screws 25 (shown in
Therefore, most of heat generated by the LEDs 11 at the time of light-on of the street light 10 is transmitted to the frame 17 via the module substrate 11a and is also transmitted from the frame 17 to the apparatus body 15. The heat of the LEDs 11 transmitted to the apparatus body 15 is released from the surface of the apparatus body 15 to the atmosphere.
The module substrate 11a has copper foil as a heat spreader. Consequently, the heat of the LEDs 11 transmitted to the module substrate 11a can be efficiently transmitted to the frame 17 by using the copper foil. The copper foil on the module substrate 11a and aluminum or silver vapor-deposited on the reflector 14 are discontinuous.
As shown in
That is, the first and second fixing parts 55 and 56 do not protrude in the width direction of the reflector 14, so that occurrence of a useless gap between neighboring reflectors 14 can be prevented as much as possible. As a result, the interval between neighboring light source modules 12 can be minimized and the interval I of the columns of the LEDs 11 can be set to the above-described value.
As shown in
Simultaneously, as shown in
The translucent cover 13 is supported by the apparatus body 15 and covers the light source modules 12, the frame 17, and the lighting device 20 from below. The translucent cover 13 is made of a synthetic resin material such as a transparent acrylic resin. The surface of the translucent cover 13 is subjected to a frosting process so that the interior of the street light 10 cannot be seen.
As shown in
The third light transmission part 63 is provided almost parallel with the second attachment part 17b of the frame 17. The third light transmission part 63 covers the first irradiation ports 52 of the plurality of light source modules 12 fixed to the second attachment part 17b from below and is disposed so as to be orthogonal to the emission direction of light reflected by the light reflection face 14a. The fourth light transmission part 64 extends obliquely upward from the lower end of the third light transmission part 63 so as to be almost orthogonal to the third light transmission part 63. The fourth light transmission part 64 is continued to the third light transmission part 63. Further, the fourth light transmission part 64 covers the second irradiation ports 53 of the plurality of light source modules 12 fixed to the second attachment part 17b from below and is disposed so as to be orthogonal to the emission direction of light reflected by the under face of the reflection wall 54.
By employing such a translucent cover 13′, there are advantages as follows. Specifically, light of LED 11 reflected by the light reflection face 14a of the light source module 12 and traveling to the first irradiation port 52 and light emitted from the LED 11 directly to the first irradiation port 52 passes through the first and third light transmission parts 61 and 63 in the translucent cover 13 as shown by arrows N in
Similarly, the light of the LED 11 reflected by the under face of the reflection wall 54 of the light source module 12 and traveling to the second irradiation port 53 and light emitted from the LED 11 directly to the second irradiation port 53 passes through the second and fourth light transmission parts 62 and 64 in the translucent cover 13 as shown by arrows M in
Therefore, loss of light when the light of the LED 11 passes through the translucent cover 13 is reduced, and the light can be efficiently emitted outside of the translucent cover 13.
Further, four faces of the first to fourth light transmission parts 61 to 64 of the translucent cover 13 shine due to the light emitted from the LEDs 11. Consequently, sufficient light can be led to places needing illumination and the appearance of the street light 10 which is turned on becomes characteristic.
In the street light 10 of the eighth embodiment of the invention, the plurality of light source modules 12 are arranged in the longitudinal direction of the apparatus body 15. The plurality of LEDs 11 of each of the light source modules 12 are arranged linearly along the longitudinal direction of the reflectors 14. Therefore, arrangement of the parts in the apparatus body 15 can be simplified and the arrangement of the LEDs 11 can be also simplified.
Further, each of the light source modules 12 arranged in the longitudinal direction of the apparatus body 15 has the reflector 14, and distribution of light emitted from the LEDs 11 is controlled by the light reflection face 14a of the reflector 14. As a result, illumination over a wide range is enabled, and appropriate brightness required by the street light 10 can be obtained.
The LEDs 11 assembled to the reflector 14 are disposed in the center portion in the width direction of the light reflection face 14a on the inside of the light reflection face 14a curved in a circular arc shape. With this arrangement, the column of the LEDs 11 arranged linearly is reflected in each of the two reflection regions 14b and 14c in the light reflection face 14a. Each of the images of the LEDs 11 reflected in the reflection regions 14b and 14c is expanded and larger than the actual size of the LED 11. That is, the existence of the light reflection face 14a makes it appear as if there are more LEDs 11 than there actually are, and makes each of the LEDs 11 look larger. Therefore, although each of the LEDs 11 is a point light source of high brightness, glare can be reduced.
In the light source module 12 of the embodiment, the distances from the LEDs 11 arranged linearly to the reflection regions 14b and 14c in the light reflection face 14a are maintained uniformly. Consequently, reflection of the light reflection face 14a with respect to each of the LEDs 11 is controlled equally. Therefore, while light to be emitted in the direction of the arrow N in
In a street light, the distribution of light emitted from a light source can be controlled by using a lens. In the case of using a lens, however, it is disadvantageous with respect to the point that brightness of the light source is increased, and a person perceives the glare more acutely. In the case where a number of LEDs are arranged to increase the quantity of light, a lens for controlling light of the LEDs becomes inevitably large, and it is disadvantageous from the viewpoint of cost.
Further, in the case of controlling light distribution by a combination of a plurality of small lenses and a plurality of LEDs, troublesomeness at the time of assembling a street light is increased. Due to light passing through the plurality of lenses, the LEDs look independent of each other, and the presence of the LEDs of high brightness increases. Therefore, it is disadvantageous that a person perceives the glare more acutely.
In contrast, in the street light 10 of the eighth embodiment of the present invention, a luminous intensity distribution is controlled by the light source module 12 in which each of the LEDs 11 appear large by using the reflection of light, so that an inconvenience as described above does not occur.
Further, in the eighth embodiment, the reflector 14 assembled with the LED 11 has the reflection wall 54 that closes the upper end of the light reflection face 14a. The under face of the reflection wall 54 is finished as a mirror face by which mainly upward light emitted from the LED in the highest position is reflected downward to the second irradiation port 53. Therefore, leakage of the light of the LED 11 above the street light 10 can be prevented, and the influence on the living space in a neighborhood and the natural environment can be reduced.
In addition, as shown by the arrows M in
According to the light intensity distribution Q shown in
With the light intensity distribution Q, a spot light of high luminous intensity can be emitted to a region just below the street light 10 as a face to be illuminated closest to the street light 10. Therefore, horizontal illuminance just below the street light 10 can be increased efficiently, and the region just below the street light 10 can be illuminated lightly. As a result, glare of the street light 10 is reduced, and the value of GR (Glare Rating) in the application as the street light 10 can be reduced.
On the other hand, in
With the light intensity distribution R, light emitted downward from the street light 10 is distributed so as to expand symmetrically with respect to the vertical line as a center. Consequently, for example, a linear road can be illuminated over a wide range in the extension direction of the road, and the horizontal illuminance can be increased by distribution of light traveling to the region just below the street light 10.
As a result, interdependently with the existence of the light intensity distribution Q, the region just below the street light 10 can be illuminated with sufficient brightness, and glare of the street light 10 is reduced. Therefore, for example, the value of GR in the application as the street light 10 can be set to 50 or less.
Moreover, as is obvious from the light intensity distribution Q shown in
The illumination apparatus of the present invention is not limited to a street light assumed to be used outdoors. For example, the present invention can be also similarly applied to an illumination apparatus for indoors for illuminating a corridor of a research facility, a library, a museum, or the like over a wide range. In an illumination apparatus assumed to be used indoors, a packing for waterproofing interposed between the apparatus body and the translucent cover need not be provided.
Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.
Number | Date | Country | Kind |
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2008-151098 | Jun 2008 | JP | national |