JP2013196868A - Led lighting system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting system using reflection light of LED emission light.SOLUTION: An LED lighting system has an LED arrangement lamp including a plurality of LEDs arranged in vertical direction, a first reflector for reflecting straight advancing light emitted from the LEDs, and a second reflector for reflecting a part or whole of the first reflection light reflected by the first reflector. Second reflection light reflected by the second reflector is irradiated to the outside of the LED lighting system from the upper rear part of the LED arrangement lamp. Especially, the second reflection light advances to the opposite direction to the straight advancing light from the LED.

Description

The present invention relates to an illuminating device using LEDs, and more particularly to an illuminating device using reflected light of LED radiation.

With the recent increase in energy problems, LED lighting that is energy-saving and has a long life is attracting attention. Most of LED bulbs that are used for LED lighting include an LED that is a light emitter and an IC that controls the LED mounted on a substrate, and directly emits light emitted from the LED. The LED is a point light source, and the emitted light from the LED is directional and has a high straightness, so that there is a problem that the LED becomes dark when the emitted light deviates from the traveling direction. Therefore, a light diffusing plate that diffuses (disperses) light and has an antiglare effect is used. For example, use of a plastic plate such as acrylic as a light diffusing plate, use of glass whose surface has been roughened by sandblasting, etc., and further coat the glass plate with paste containing low melting glass powder and inorganic filler, heat treatment, and diffuse An antiglare glass having a film formed thereon has also been proposed. (Patent Document 1, Patent Document 2)

JP-A-10-81545 Patent 4875198

However, acrylic or the like used as a light diffusing plate has a problem of low transmittance. Further, there is a concern that the strength of the glass whose surface is roughened by sandblasting or the like is lowered. On the other hand, the antiglare glass having a light-diffusing film has an inorganic filler added, so that the transmittance is lowered and the haze value is insufficient. Moreover, since there are few disclosures of the illuminating device using the reflected light of LED radiation light, and there are few actual utilization, a technical element is not provided.

The present invention has been made in view of the above circumstances, and proposes an illumination method that uses reflected light without directly using the emitted light from the LED. The main components of the present invention are as follows. It is as follows.
(1) The present invention relates to an LED array lamp including a plurality of LEDs arranged in the vertical direction or in the vertical and horizontal directions, a first reflecting mirror that reflects straight light emitted from the LEDs, and the first An LED lighting device having a second reflecting mirror that reflects part or all of the first reflected light reflected by the reflecting mirror of
The second reflected light reflected by the second reflecting mirror is irradiated to the outside of the LED lighting device from the upper rear of the LED array lamp, and particularly the second reflected light. Travels in the opposite direction to the straight light from the LED.

(2) In addition to the above, in the present invention, in the n LED rows arranged in the vertical direction, the incident angle at which the straight light emitted from the lowermost LED (L1) enters the first reflecting mirror is set. α1, the incident angle at which the straight LED light emitted from the i-th LED (Li) counted from the lowermost LED (L1) is incident on the first reflecting mirror is αi, and the uppermost LED (i = n) When the incident angle at which the emitted straight LED light enters the first reflecting mirror is αn, the first reflecting mirror satisfies α1 <... <Αi-1 <αi <αi + 1 <. Or a smooth and continuous (differentiable) curved surface, or the first reflecting mirror is a plane mirror, and LEDs (Li) (i = i = n) in n LED rows arranged in the vertical direction. 1,..., I,..., N) The incident angle at which the LED straight light emitted is incident αi is characterized in that αi = α (constant).

(3) In addition to the above, in the present invention, in the n LED rows arranged in the vertical direction, the first reflected light of the LED straight light emitted from the lowermost LED (L1) is the second reflecting mirror. The incident angle at which the first reflected light of the straight LED light emitted from the i-th LED (Li) counted from the lowermost LED (L1) is incident on the second reflecting mirror is β1. βi, where βn is an incident angle at which the first reflected light of the straight LED light emitted from the uppermost LED (i = n) is incident on the second reflecting mirror, β1> · ..> βi-1 <βi <βi + 1 <... <Βn, and is a smooth and continuous (differentiable) curved surface, or the second reflecting mirror is a plane mirror, LEDs (Li) (n = 1,..., I,...) In n LED rows arranged in the direction. The incident angle βi at which the first reflected light of the straight LED light emitted from n) enters the second reflecting mirror is βi = β (constant).

(4) In addition to the above, the present invention is characterized in that 80 degrees <αi + βi <90 degrees, preferably 85 degrees <αi + βi <95 degrees, and most preferably αi + βi = 90 degrees.
(5) In addition to the above, the present invention is characterized in that the second reflecting mirror is made of transparent glass or transparent plastic, and the first reflected light incident on the second reflecting mirror is totally reflected.

The illumination device of the present invention uses the reflected light of LED radiation for illumination. According to the present invention, the reflected light of the desired LED radiation can be used as illumination. Since the size and shape of the device can be designed according to the application, it is highly practical. Since the LED radiation is moderately dispersed by the first reflecting mirror and the second reflecting mirror, it is possible to solve the problem that the periphery of the conventional LED bulb, which is a problem, is dark. Since the light transmitted through the diffusion plate and the coating material is not used, problems such as a decrease in transmittance and haze do not occur. It is also possible to emit light in the direction opposite to the direction of the LED. The LED light source is copied as a virtual image on the reflecting mirror and can be easily viewed from the outside. Since the light from the LED array lamp in which a plurality of LEDs are arrayed can also be taken out in parallel, predetermined illumination can be obtained.

FIG. 1 is a diagram showing a first embodiment of the LED lighting device of the present invention. FIG. 2 is a diagram showing a case where the angle γ formed by the first reflecting mirror (plane mirror) and the second reflecting mirror (plane mirror) is smaller than 90 degrees. FIG. 3 is a diagram showing a case where the angle γ formed by the first reflecting mirror (plane mirror) and the second reflecting mirror (plane mirror) is larger than 90 degrees. FIG. 4 is a diagram showing another embodiment of the present invention in which the reflecting mirror is a curved surface. FIG. 5 is a diagram showing a design example in which the second reflecting mirror shown in FIG. 4 is miniaturized. FIG. 6 is a diagram showing an embodiment in the case where the second reflected light and the first reflected light are mixed and irradiated behind the LED array lamp. FIG. 7 is a diagram showing an application example of the present invention. FIG. 8 is a diagram showing reflected light when the LED array lamp is placed horizontally (horizontal) and a (planar) reflecting mirror is used. FIG. 9 is a diagram showing an embodiment of an LED illumination device 61 having an LED matrix array lamp (m-row × n-column LED matrix surface light source), a first reflecting mirror corresponding thereto, and a second reflecting mirror. .

The present invention provides an illuminating device in which LED radiation light having high directivity and straightness is reflected by a reflecting mirror so that the LED light source can be visually recognized while being appropriately dispersed, and the surroundings can be illuminated brightly.

FIG. 1 is a diagram showing a first embodiment of the LED lighting device of the present invention. The LED illumination device 11 of the present invention includes an LED array lamp 13, a first reflecting mirror (planar reflecting mirror) 15, and a second reflecting mirror (planar reflecting mirror) 17. In FIG. 1, a plurality (n) of LEDs (L1,..., Li,..., Ln) are arranged in one direction (in terms of expression and basically when setting a lighting device, LED array lamps 13 arranged in the following “vertical direction”), and light rays (with straightness) from a plurality (n) of LEDs of this LED array lamp 13 are unidirectional (perpendicular to the vertical direction), (Referred to as a lateral direction for the sake of expression). That is, the straight light from each LED is a parallel light beam traveling in the lateral direction.

The first reflecting mirror 15 on which the straight light emitted from these LEDs is incident and reflected is arranged with an incident angle α with respect to the straight light in the direction (lateral direction) of the straight light of the LED array lamp 13. Has been. Since the first reflecting mirror 15 shown in FIG. 1 is a plane reflecting mirror, the angle of reflection with respect to straight light from each LED is also constant and is α. That is, each first reflected light is a parallel light beam.

The reflected light (first reflected light) obtained by the straight light from the LED array lamp 13 reflected by the first reflecting mirror (planar mirror) 15 is then incident on the second reflecting mirror 17 and reflected light (second reflected light). The second reflected light then goes out of the LED lighting device. If the incident angle formed by the first reflected light and the second reflecting mirror 17 is β, the second reflecting mirror 17 is a plane (reflecting) mirror, and therefore the second reflecting mirror for each first reflected light. The reflection angle of the second reflected light from 17 is also constant and β. That is, each 2nd reflected light turns into a parallel ray. If the angle formed by the first reflecting mirror 15 and the second reflecting mirror 17 is γ, α + β = γ.

For example, the straight line radiated from the LED (L1) at the lowermost part of the LED array lamp 13 (the LED having the closest distance to the first reflecting mirror 15 among the LEDs in the LED array lamp 13 arranged in the vertical direction) The light P1 enters the first reflecting mirror 15 and is reflected (incident angle = reflection angle = α) to become the first reflected light P1-1. The first reflected light P1-1 is incident on and reflected by the second reflecting mirror 17 (incident angle = reflecting angle = β) to become the second reflected light P1-2.

Moreover, the straight line radiated | emitted from LED (Ln) in the uppermost part (LED in the LED array lamp 13 arrange | positioned in the vertical direction is the furthest distance from the 1st reflective mirror 15) of the LED array lamp 13 The light Pn is incident on and reflected by the first reflecting mirror 15 (incident angle = reflection angle = α), and becomes the first reflected light Pn−1. The first reflected light Pn−1 is incident on and reflected from the second reflecting mirror 17 (incident angle = reflecting angle = β) to become the second reflected light Pn−2.

A straight light Pi from the Li (i = 2 to n-1, arranged in this order) of each LED arranged between L1 and Ln of the LED array lamp 13, a first reflected light Pi-1, The second reflected light Pi-2 has the same relationship. (Pi, Pi-1, Pi-2 are not shown) Further, the straight light P1,..., Pi,..., Pn are parallel, and the first reflected light P1-1,. Pi-1,..., Pn-1 are parallel, and the second reflected lights P1-2, ..., Pi-2, ..., Pn-2 are parallel. Further, the straight light P1, ..., Pi, ..., Pn and the first reflected light P1-1, ..., Pi-1, ..., Pn-1 exist in the LED illumination device 11. However, the second reflected light P1-2,..., Pi-2,..., Pn-2 is radiated to the outside of the LED illumination device 11 to irradiate an external object or space, and the LED from the outside. Can be visually recognized. Further, as can be seen from FIG. 1, when the LED array lamp 13 is confirmed from the outside, it is on the reverse direction side R2 unlike the direction of R1. Moreover, the size is also different. (R1 ≠ R2)

In FIG. 1, the angle γ formed by the first reflecting mirror (plane mirror) 15 and the second reflecting mirror (plane mirror) 17 is depicted as 90 degrees. At this time, the second reflected light Pi-2 (i = 1 to n) is a light beam in the opposite direction and parallel to the straight light Pi (i = 1 to n). That is, the direction of the second reflected light Pi-2 (i = 1 to n) is 180 degrees with respect to the direction of the straight light Pi (i = 1 to n). When viewed from the direction of the LED array lamp 13, the direction of the second reflected light Pi-2 (i = 1 to n) is the lateral direction, and is emitted to the upper rear side of the LED array lamp 13. That is, the LED array light 13, the first reflecting mirror (planar mirror), and the 15 and second reflecting mirror (planar mirror) 17 make the LED radiation light into a parallel reflected light beam, and the LED illumination device 11 on the upper rear side thereof. You can illuminate objects and spaces outside.

Strictly speaking, the LED is not a perfect point (or line) light source but has a certain width, and the radiation direction is not the same direction but is spread to some extent. Furthermore, there is also a spread variation in reflected light due to a variation in LED arrangement due to a mounting method when a plurality of LEDs are arranged on a substrate or the like to produce an LED array lamp. Moreover, even if it says that there is a straight line, it gradually scatters and spreads as the distance increases. It is also necessary to consider the case where the actual incident angle and reflection angle of the reflecting surfaces of the first reflecting mirror and the second reflecting mirror vary. Furthermore, since the LED may be covered with a cap, the LED light is dispersed. Therefore, when LED light is taken out in a certain direction, it is necessary to consider a certain width. Therefore, even when the second reflected light of the emitted light of the LED is extracted in a certain direction, it is necessary to allow the range of the angle γ formed by the first reflecting mirror and the second reflecting mirror within a certain range. For example, in order to irradiate the LED light in a direction having a certain width with respect to the complete rear direction (180 degree direction with respect to the straight light of the LED) (when taking out), preferably, 80 degrees <γ = α + β <100 Degrees, more preferably 85 degrees <γ = α + β <95 degrees, and most preferably, γ = α + β = 90 degrees with respect to the LED array lamp 13 with respect to the LED array lamp 13. It is good to arrange.

FIG. 2 shows a case where the angle γ formed by the first reflecting mirror (plane mirror) 15 and the second reflecting mirror (plane mirror) 17 is smaller than 90 degrees. Since α + β = γ, α + β = γ <90 degrees. As shown in FIG. 2, the second reflected light Pi-2 (i = 1 to n) is opposite to the straight light Pi (i = 1 to n), but is lower than the parallel rays. When viewed from the direction of the LED array lamp 13, the direction of the second reflected light Pi-2 (i = 1 to n) is lower than the lateral direction and becomes a parallel light beam behind the LED array lamp 13. Radiated. As can be seen from FIG. 2, the second reflected light Pn-2 of the straight light emitted from the LED (Ln) hits the upper part of the LED array lamp 13 and may not be emitted to the outside. 1, the first incident angle α from the straight light Pi from the LED, the size of the LED array lamp 13 and the first reflecting mirror 15, the first reflecting mirror 15 and the second reflecting mirror 17. It needs to be adjusted.

FIG. 3 shows a case where the angle γ formed by the first reflecting mirror (plane mirror) 15 and the second reflecting mirror (plane mirror) 17 is greater than 90 degrees. (However, γ <180 degrees.) Since α + β = γ, α + β = γ> 90 degrees. The second reflected light Pi-2 (i = 1 to n) is in the opposite direction to the straight light Pi (i = 1 to n), but is more upward than the lateral light beam. When viewed from the direction of the LED array lamp 13, the direction of the second reflected light Pi-2 (i = 1 to n) is higher than the lateral direction, and is emitted to the rear of the LED array lamp 13. As can be seen from FIG. 1 to FIG. 3, by combining two plane reflecting mirrors, straight light from the LED is radiated to the rear of the LED, and the parallel light beams irradiate an object or space behind the LED. can do. Further, by adjusting the angle γ of the two plane reflecting mirrors, an LED illumination device that irradiates the rear lower side, the 180 degree (complete rear) direction, or the rear upper side of the LED array lamp can be manufactured. These directions can be appropriately selected depending on the application (for example, when selecting the irradiation direction).

FIG. 4 is a diagram showing another embodiment of the present invention in which the reflecting mirror is a curved surface. The illuminating device 21 of the present invention shown in FIG. 4 has an LED array lamp 23, a first curved reflector 25, and a second curved reflector 27. When the straight light P1 radiated from the lowermost LED L1 of the LED array lamps 23 is incident on the first curved reflecting mirror 25, it is reflected at the incident point D1 and becomes the first reflected light P1-1. If the tangent plane of the first curved reflecting mirror 25 at the incident point D1 is G1, the angle formed by the normal of the tangential plane G1 and the straight light P1 at the incident point D1 is the incident angle, and if this is α1, the reflection angle The reflected light P1-1 advances at α1. The first reflected light P1-1 is then reflected at the incident point E1 of the second curved reflecting mirror 27 to become the second reflected light P1-2. Assuming that the tangent plane of the second curved reflecting mirror 27 at the incident point E1 is H1, the angle formed by the tangential plane H1 and the normal line of the first reflected light P1-1 at the incident point E1 is the incident angle, which is β1. Then, the reflected light P1-2 proceeds at the reflection angle β1, and is emitted to the outside of the LED illumination device 21 to irradiate an object or space outside the LED illumination device 21.

When the straight light Pn radiated from Ln of the uppermost LED in the LED array lamp 23 is incident on the first curved reflecting mirror 25, it is reflected at the incident point Dn and becomes the first reflected light Pn-1. If the tangent plane of the first curved reflecting mirror 25 at the incident point Dn is Gn, the angle between the normal of the tangential plane Gn and the straight light Pn at the incident point Dn is the incident angle, and αn is the reflection angle. The first reflected light Pn-1 advances at αn. The first reflected light Pn−1 is then reflected at the incident point En of the second curved reflecting mirror 27 to become the second reflected light Pn-2. Assuming that the tangent plane of the second curved reflecting mirror 27 at the incident point En is Hn, the angle formed between the normal line of the tangential plane Hn and the first reflected light Pn−1 at the incident point En is the incident angle, which is βn. Then, the reflected light Pn-2 travels at the reflection angle βn and is emitted to the outside of the LED illumination device 21 to irradiate an object or space outside the LED illumination device 21.

When the straight light Pi radiated from the Li of the LED between the Ln of the uppermost LED and the L1 of the lowermost LED of the LED array lamps 23 is incident on the first curved reflecting mirror 25, at the incident point Di. Reflected to become the first reflected light Pi-1. If the tangent plane of the first curved reflecting mirror 25 at the incident point Di is Gi, the angle between the normal of the tangential plane Gi and the straight light Pi at the incident point Di is the incident angle, and αi is the reflection angle. The first reflected light Pi-1 advances at αi. Next, the first reflected light Pi-1 is reflected at the incident point Ei of the second curved reflecting mirror 27 to become the second reflected light Pi-2. Assuming that the tangent plane of the second curved reflecting mirror 27 at the incident point En is Hi, the angle between the normal line of the tangential plane Hi and the first reflected light Pi-1 at the incident point Ei is the incident angle, which is βi. Then, the reflected light Pi-2 travels at the reflection angle βi and is emitted to the outside of the LED illumination device 21 to irradiate an object or space outside the LED illumination device 21.

If the angle between the tangential plane Gi and the tangential plane Hi is γi, then αi + βi = γi. As described with reference to FIGS. 1 to 3, when 0 <γi <90 degrees, the second reflected light Pi-2 (i = 1 to n) is opposite to the straight light Pi (i = 1 to n). Yes, but below the transverse ray. When viewed from the direction of the LED array lamp 23, the direction of the second reflected light Pi-2 (i = 1 to n) is lower than the lateral direction, and is emitted to the upper rear side of the LED array lamp 23. If γi = γ0 (constant) (i = 1, 2,..., n), the second reflected light of each LED radiation light is a parallel light beam. When 90 degrees <γi <180 degrees, the second reflected light Pi-2 (i = 1 to n) is opposite to the straight traveling light Pi (i = 1 to n), but is more upward than the lateral light beam. Become. When viewed from the direction of the LED array lamp 23, the direction of the second reflected light Pi-2 (i = 1 to n) is higher than the lateral direction, and is emitted to the upper rear side of the LED array lamp 23. If γi = γ0 (constant) (i = 1, 2,..., n), the second reflected light of each LED radiation light is a parallel light beam.

When γi = 90 degrees, the second reflected light Pi-2 (i = 1 to n) is a light beam in the opposite direction and parallel to the straight traveling light Pi (i = 1 to n). That is, the direction of the second reflected light Pi-2 (i = 1 to n) is 180 degrees with respect to the direction of the straight light Pi (i = 1 to n). When viewed from the direction of the LED array lamp 23, the direction of the second reflected light Pi-2 (i = 1 to n) is the lateral direction (direction of 180 degrees), and is emitted to the upper rear side of the LED array lamp 23. . In other words, the LED array lamp 23 can illuminate an object or space outside the LED illumination device 21 behind (upper right behind) the LED illumination device 21. The second reflected light of each LED radiation is a parallel light beam.

Strictly speaking, the LED is not a perfect point (or line) light source but has a certain width, and the radiation direction is not the same direction but is spread to some extent. Furthermore, there is also variation due to variation in LED arrangement due to a mounting method when a plurality of LEDs are arranged on a substrate or the like to produce an LED array lamp. Moreover, even if it says that there is a straight line, it gradually scatters and spreads as the distance increases. It is also necessary to consider the case where the actual incident angle and reflection angle of the reflecting surfaces of the first reflecting mirror and the second reflecting mirror vary. Further, when the LED is covered with a cap, it is emitted with a certain extent.

Therefore, when LED light is taken out in a certain direction, it is necessary to consider a certain width. Therefore, even when the second reflected light of the emitted light of the LED is extracted in a certain direction, it is necessary to allow the range of the angle γ formed by the first reflecting mirror and the second reflecting mirror within a certain range. For example, in order to irradiate the LED light in a direction having a certain width with respect to the complete rear direction (180 degree direction with respect to the straight light of the LED) (when taking out), preferably, 80 degrees <γ = α + β <100 Degrees, more preferably 85 degrees <γ = α + β <95 degrees, and most preferably, γ = α + β = 90 degrees, with respect to the LED array lamp 23 with respect to the LED array lamp 23. It is good to arrange.

The second reflected light Pi-2 of each LED (Li (i = 1 to n), n is a positive integer) in the LED array lamp 23 is the second reflected light P1-2 and Pn-2 in this order. In order to exist between them, with respect to the incident angle αi (i = 1 to n), 90 degrees−α1 <... <90 degrees−αi <... <90 degrees−αn, that is, α1>. A curved surface 25 having a tangent plane Gi (i = 1 to n) such that> αi>. And with respect to the incident angle βi (i = 1 to n), 90 degrees−β1>...> 90 degrees−βi>...> 90 degrees−βn, that is, β1 <. A curved surface 27 having a tangential plane Hi (i = 1 to n) that becomes βn may be produced.

Furthermore, since the first curved reflector 25 is smoothly continuous, the curve of the first curved reflector 25 connecting D1,..., Di,. Must be differentiable. Since the second curved reflecting mirror 27 is also smoothly continuous, the curve of the second curved reflecting mirror 27 connecting E1,..., Ei,. Need to be.

Furthermore, as described above, α + β = γ holds, and, for example, to irradiate the second reflected light completely (180 degrees) rearward with respect to the LED array lamp 23, α + β = γ = 90 degrees, Considering the variation (constant width), preferably 80 degrees <γ = α + β <100 degrees, more preferably 85 degrees <γ = α + β <95 degrees, and most preferably γ = α + β = 90 degrees. In addition, it is not necessary to connect the first curved reflector 25 and the second curved reflector 27, and it is not necessary to provide a curved reflector in the portion of the LED array lamp 23 where the reflected light of the LED does not reach. For example, in FIG. 4, since the curved surface between Dn on the first curved reflecting mirror 25 and the point E1 of the second curved reflecting mirror 27 is unnecessary, the LED illumination device 21 can be downsized.

FIG. 5 is a diagram showing a second reflecting mirror 29 in which the second reflecting mirror 27 shown in FIG. 4 is reduced in size. When a tangential plane H1 ′ parallel to the tangential plane H1 is produced at the point E1 ′ between the points D1 and E1 in the first reflected light P1-1 of the LED (L1), the incident angle β1 is obtained at the point E1 ′. To obtain the second reflected light P′1-2 having the reflection angle β1. An intersection point Ei ′ with the tangential plane Hi ′ is formed so as to be smoothly continuous (a differentiable curve) at the point E1 ′ on the first reflected light Pi−1 of Li (i = 2 to n) of each LED. The second reflected light P′i−2 having the reflection angle βi with respect to the incident angle βi is obtained at the intersection Ei ′. By repeating this up to the En ′ point, a new second curved reflecting mirror 29 can be obtained. Thus, a large number of second curved reflecting mirrors can be produced and can be made to correspond to the size of the LED lighting device. On the other hand, another curved reflecting mirror can be produced for the first curved reflecting mirror 25. That is, since the first curved reflector 25 can be produced in a number of other curved reflectors that are smoothly continuous (become differentiable curves), the first curved reflector 25 is also an LED lighting device. Can correspond to the size. As described above, the LED array lamp, the first reflecting mirror, and the second reflecting mirror having a desired size and shape can be appropriately selected according to the application and size of the LED lighting device.

FIG. 6 is a diagram showing an embodiment in the case where the second reflected light and the first reflected light are mixed and irradiated behind the LED array lamp. The straight light P1 emitted from L1 which is the lowermost LED of the LED array lamp 33 is incident at the point D1 of the first curved reflecting mirror 35 with an incident angle α1, and has a reflection angle α1 at the point D1. It is reflected and becomes the first reflected light P1-1. The first reflected light P1-1 enters at the point E1 of the second curved reflecting mirror 37 with an incident angle β1, and is reflected at the point E1 with a reflection angle β1 to be reflected by the second reflected light P1−. 2 The second reflected light P1-2 is radiated to the outside of the LED illumination device 31 and irradiates an external object or space.

The straight traveling light Pn emitted from Ln which is the uppermost LED of the LED array lamp 33 is incident at the point Dn of the first curved reflecting mirror 35 with an incident angle αn, and has a reflection angle αn at the point Dn. It is reflected and becomes the first reflected light Pn-1. The first reflected light Pn−1 is emitted outside the LED illumination device 31 without being incident on the second curved reflecting mirror 37 to irradiate an external object or space. Therefore, there is no second reflected light.

The straight light Pi radiated from Li, which is an LED arranged between Ln, which is the uppermost LED of the LED array lamp 33, and L1, which is the lowermost LED, is the Di point of the first curved reflector 35. And incident at an angle of incidence αi and reflected at the point Di with a reflection angle αi to be the first reflected light Pi-1. When i ≦ m−1, the first reflected light Pi−1 has the incident angle βi at the point Ei of the second curved reflecting mirror 37 and is second as in the case of the first reflected light P1-1. , And is reflected at the point Ei with a reflection angle βi to become the second reflected light Pi-2. The second reflected light Pi-2 is emitted to the outside of the LED illumination device 31 and irradiates an external object or space. On the other hand, when the first reflected light Pi-1 is i ≧ m, the first reflected light Pi-1 is not incident on the second curved reflecting mirror 37, similarly to the first reflected light Pn-1. The light is emitted to the outside of the LED illumination device 31 to irradiate an external object or space.

As described above, in this embodiment, the straight light from all the LEDs of the LED array lamp 33 enters the first curved reflecting mirror 35 and is reflected to become the first reflected light. This first reflection In the case where light does not enter the second curved reflecting mirror 35 and is emitted as it is to the outside of the LED lighting device 31, the first reflected light enters the second curved reflecting mirror 35 and the second There are cases where the light is reflected and emitted outside the LED lighting device 31. That is, the first reflected light and the second reflected light are mixed and emitted to the outside of the LED lighting device 31 to irradiate an external object or space. Even in such a mixed type, it is possible to irradiate an external object or space by emitting reflected light of the LED to the rear of the LED array lamp 33.

FIG. 7 is a diagram showing an application example of the present invention. FIG. 7 shows a plurality of LEDs (Li (i = 1,..., A,..., B,. N), an LED array lamp 43 having a lowermost LED L1 and an uppermost LED Ln) is disposed. The substantially half curved reflectors 47 and 48 on the upper side of the curved reflector are made of transparent glass or transparent plastic. The straight-ahead light radiated from the LED (L1) is reflected by the lower curved reflecting mirror 45 in front of the LED to become reflected light (first reflected light), and enters the upper curved reflecting mirror 47. Since the upper curved reflector 47 is made of transparent glass or transparent plastic, a part of it is reflected and becomes reflected light Q1 (second reflected light) to the upper rear side of the LED array lamp 43. The reflected light Q1 is incident on the curved reflecting mirror 48 on the upper rear side of the LED array lamp 43. A part of the light passes through the curved reflector 48 and is emitted to the outside of the LED illumination device 41 to irradiate an object or space outside. Alternatively, the LED can be visually recognized by looking at the eyes. Without the curved reflecting mirror 48, all the reflected light Q1 reflected by the curved reflecting mirror 48 is radiated to the outside of the LED illumination device 41. Radiated light from other LEDs (for example, La and Lb) is also reflected by the lower curved reflector 45, and this reflected light (first reflected light) is incident on the upper curved reflector 47, and further on the upper side. The reflected light (for example, Qa, Qb) (second reflected light) reflected by the curved reflecting mirror 47 is incident on the curved reflecting mirror 48 on the upper rear side of the LED array lamp 43, and a part thereof is the curved reflecting mirror 48. Is transmitted to the outside of the LED illumination device 41 to irradiate an object or space outside.

A part of the light incident on the upper curved reflecting mirror 47 is transmitted and emitted to the outside of the LED illumination device 41, so that the outside is also irradiated and the LED light can be visually recognized. However, if the light incident on the curved reflecting mirror 47 can be totally reflected, the efficiency of back irradiation with the reflected light Q1 or the like can be increased. Since the curved reflecting mirror 47 is made of transparent glass or transparent plastic, incident light enters the curved reflecting mirror 47. Normally, this light is transmitted to the outside while being absorbed or scattered inside the curved reflecting mirror 47. However, when the refractive index of the curved reflecting mirror 47 is g47, sin β1> 1 / g47 is satisfied. Sometimes, it is totally reflected without transmitting to the outside of the curved reflecting mirror 47. For example, when g47 = 1.5, the incident angle β1 may be adjusted so that sin β1> 0.67, that is, β1> 42 degrees. Note that when the light is incident on the curved reflecting mirror 47, a part of the light is scattered or reflected and lost, so that the liquid space in the LED lighting device 41 is the same (or close) as the refractive index of the curved reflecting mirror 47. By filling with a material, the efficiency of the totally reflected light can be increased. For example, the curved reflecting mirror 47 may be made of glass having a refractive index of 1.5, and the liquid material may be paraffin oil (refractive index of 1.48).

In FIG. 7, as in FIG. 6, not all of the first reflected light from the LED is incident on the upper curved reflector 47 that is the second reflector, but the LED ( The first reflected light from Li,..., Ln) is incident on the curved reflecting mirror 48 on the upper rear side of the LED array lamp 43, for example, as Qi,. The light passes through the mirror 48 and is emitted to the outside of the LED illumination device 41 to irradiate an object or space outside.

Let Di be the place where the straight light from the LED (Li) enters the curved reflecting mirror 45, and let αi be the incident angle. When the distance from the LED (Li) to Di is ti, and the length from the LED (Li) to the top of the LED array lamp (the top that blocks the first reflected light) is hi, the first reflected light Qi is In order not to block, it is only necessary to satisfy hi <ti (tan 2αi). Further, if the distance from the LED (Li) to the uppermost portion of the upper curved reflector 47 is ui, in order to prevent the first reflected light Qi from entering the upper curved reflector 47, ui> ti ( tan2αi). By designing as described above, the emitted light from the LED arranged on the lower side of the LED array lamp is reflected twice and emitted to the outside, and the emitted light from the LED arranged on the upper side of the LED array lamp is emitted. The LED illumination device 41 shown in FIG. 7 can be produced that is reflected only once and is emitted to the outside behind the LED device 43.

If the curved reflecting mirrors 45, 46 and 47, 48 in the LED lighting device 41 shown in FIG. 7 are rotating bodies (for example, elliptical spheres), light is emitted in all directions by rotating the LED array lamp 43. can do. (For example, it can be used like a mirror ball.) The LED illumination device 41 itself may be rotated, but since the LED illumination device 41 itself is not moved (rotated), a mysterious atmosphere can be produced. Since the LED shown in FIG. 7 has a cap in the traveling direction of the LED, it is emitted as a little broad light by this cap. This may be interpreted as LED radiation having a certain width as described above.

FIG. 8 is a diagram showing reflected light when the LED array lamp 53 is placed horizontally (horizontal) and a (planar) reflecting mirror 55 is used. When the LED array lamp 53 is placed horizontally (horizontal) and the incident angle from the LEDs (L1,..., Ln) of the LED array lamp 53 to the (planar) reflecting mirror 55 is α, each of the LED array lamps 53 is arranged. The light emitted from the LEDs (L1,..., Li,..., Ln) is the first reflected light Qi (i = 1, 2,...) In the lateral (horizontal) direction when 0 <α <90 degrees. , N) is reflected and goes out of the LED illumination device 51 to irradiate an external object or space. Moreover, LED can be visually recognized from the outside. When 0 <α <45 degrees, the first reflected light Qi is emitted downward in parallel, but the first reflected light Qi may strike the LED array lamp 53 depending on the angle α. When 45 degrees <α, the first reflected light Qi is emitted upward in parallel. When α = 45 degrees, the first reflected light Qi is emitted in parallel in the lateral direction, and is irradiated backward as viewed from the device 51. When the LED array lamp 53 is placed sideways in this manner, reflected light (irradiation light) to the rear can be obtained with a single (planar) reflecting mirror 55.

The LED lighting device of the present invention is a device that irradiates the reflected light, which is reflected by a reflecting mirror, with a highly directional straight beam from the LED, but is appropriately diffused and dispersed by the reflecting mirror, and is also appropriately spread. Since it radiates to the outside, it becomes broader light and the surroundings are relatively brighter than the straight light from the LED. Moreover, since the reflecting mirror is used, there is an advantage that the LED light source can be visually recognized. In FIG. 1 to FIG. 7, the LED array lamps are described in a single line with respect to the vertical direction, but a plurality of LED array lamps may be arranged on the depth side. In this case, each reflecting mirror (first reflecting mirror, second reflecting mirror) having the same size and shape may be fabricated on the depth side, or may be fabricated with a curved surface on the depth side. Also good. Since the curved surfaces on the depth side can use a large number of curved reflecting mirrors as described above, they may be appropriately designed based on the conditions described in the present invention. Alternatively, the above-described flat mirror may be used as the first reflecting mirror, the above-described curved reflecting mirror may be used as the second reflecting mirror, or the above-described curved reflecting mirror may be used as the first reflecting mirror. Alternatively, the above-described planar reflecting mirror may be used as the second reflecting mirror. When these are appropriately combined, as described in FIG. 6 and FIG. 7, a part of the first reflected light may be radiated as it is to the rear of the LED array lamp, but such a method is used depending on the application. May be selected as appropriate. The reflecting mirror described in the present invention is, for example, a spherical surface, an ellipsoid, a hyperboloid,
Or it is a conical surface. Moreover, the material which is normally used, such as glass, a plastics, and a metal, can be used as a reflecting mirror. The reflective surface may be coated with a reflective coating film or a metal film.

FIG. 9 has LEDs (Lij (i = 1,..., M; j = 1,..., N)) arranged in a matrix form of m in the vertical direction (Z direction) and n in the horizontal direction (X direction). LED array lamp (m-row xn-column LED matrix surface light source, for example, 12 rows, 12 columns, 24 rows, 24 columns, 24 rows, 36 columns, and the like can be variously created) 63, a first reflecting mirror 65 corresponding to this, and a second It is a figure which shows one Embodiment of the LED illuminating device 61 which has the reflective mirror 67. The LED illuminating device 61 in FIG.9 is shown in three dimensions.This mxnLED array lamp has LED in matrix form in one board | substrate. However, it can be thought of as an LED array light in which m L LEDs are arranged in a row in the vertical direction (Z direction), and L pieces of L11,. LED lighting device explained based on FIG. 1 to FIG. 9, the LED array lamp 63 and the reflected light Qij (i = 1,..., M; j = 1,..., N) generated by the straight light emitted from the LED array lamp 63 are easily understood. Although the first reflecting mirror 65 and the second reflecting mirror 67 are shown by broken lines, the first reflecting mirror 65 and the second reflecting mirror 67 are actually continuous curved surfaces. The upper rear is open to emit reflected light (or it may be covered with transparent glass or plastic as shown in FIG. 7).

The straight-ahead light from the LEDs (Lij) (i = 1,..., M) in the j-th row arranged side by side is reflected by the curved surface (curve) Sj of the first reflecting mirror, and this first reflected light is reflected. The light is reflected by the curved surface (curve) Tj of the second reflecting mirror and goes out of the LED illumination device 61 as the second reflected light Qij. If the conditions described with reference to FIGS. 1 to 7 are satisfied, the reflected light Qij goes out to the rear outside (reverse Y direction) of the LED array lamp 63. As described above, Sj may not be the same curve (j = 1 to n), and Tj may not be the same curve (j = 1 to n). In that case, the first reflecting mirror 65 is curved (Oi) on the n-row side (X direction) as shown in FIG. 9, and the second reflecting mirror 67 is also as shown in FIG. A curve (Ui) is formed on the n-row side (X direction). When the angle formed by the tangent plane in the first reflecting mirror 65 and the tangential plane in the second reflecting mirror 67 has 90 degrees, the second reflected light Qil is LED-illuminated in the direction opposite to the LED straight light (reverse Y direction). The light is radiated to the outside from the upper rear opening of the lamp 61. That is, all Qij are emitted as parallel rays in the reverse Y direction, and illuminate an external object or space. When Sj and / or Tj are the same curve, as described above, the depth side (X direction) is the same curved surface. Alternatively, when Sj and / or Tj is a straight line (plane mirror), the depth side (X direction) is also the same plane mirror. In addition, although it described as an m-row xn-column LED matrix surface light source in the above, it cannot be overemphasized that it includes also about what remove | eliminated one part in it. For example, a case where the corner side of the matrix plane is omitted and a case where a part inside the matrix plane is omitted are included.

In addition, it cannot be overemphasized that the said content can be applied to the said other part regarding that it can apply without contradiction also to the other part which was not described about the content described and demonstrated in a certain part of the specification. Furthermore, the above-described embodiment is an example, and various modifications can be made without departing from the scope of the invention. Needless to say, the scope of rights of the present invention is not limited to the above-described embodiment.

The LED lighting device using the reflecting mirror of the present invention can be used not only as a lighting device but also as a toy and an ornament.

11 ... LED lighting device, 13 ... LED array lamp,
15 ... 1st reflecting mirror (planar reflecting mirror), 17 ... 2nd reflecting mirror (planar reflecting mirror),
21 ... LED lighting device, 23 ... LED array lamp,
25 ... 1st curved reflector, 27 ... 2nd curved reflector,
29 ... second curved reflector,
31 ... LED lighting device, 33 ... LED array lamp,
35 ... 1st curved reflector, 37 ... 2nd curved reflector,
41 ... LED lighting device, 43 ... LED array lamp,
45... First curved reflector, 46... First curved reflector,
47 ... second curved reflector, 48 ... second curved reflector,
49 ... Space inside the LED lighting device,
51 ... LED lighting device, 53 ... LED array lamp,
55 ... plane reflector,
61 ... LED lighting device,
63 ... LED array lamp (m row xn column LED matrix surface light source),
65 ... first (curved surface) reflecting mirror, 67 ... second (curved surface) reflecting mirror,

Claims (9)

An LED array lamp including a plurality of LEDs arranged in the vertical direction or in the vertical direction and the horizontal direction, a first reflecting mirror that reflects straight light emitted from the LEDs, and the first reflecting mirror that is reflected by the first reflecting mirror An LED lighting device having a second reflecting mirror that reflects part or all of the first reflected light,
The LED illumination apparatus, wherein the second reflected light reflected by the second reflecting mirror is irradiated to the outside of the LED illumination apparatus from above the LED array lamp. The LED illumination device, wherein the second reflected light travels in a direction opposite to the straight light from the LED. In the n LED rows arranged in the vertical direction, the incident angle at which the straight light emitted from the lowermost LED (L1) is incident on the first reflecting mirror is α1, and the incident angle from the lowermost LED (L1) is counted. The incident angle at which the LED straight light emitted from the i-th LED (Li) enters the first reflector is αi, and the LED straight light emitted from the uppermost LED (i = n) is the first reflector. When the incident angle incident on is αn,
The first reflecting mirror is a curved surface satisfying α1 <... <αi-1 <αi <αi + 1 <... <αn, and is a smooth and continuous (differentiable) curved surface, The LED lighting device according to claim 1 or 2. The first reflecting mirror is a plane mirror, and LED straight light emitted from LEDs (Li) (i = 1,..., I,..., N) in n LED rows arranged in the vertical direction. The LED illumination device according to claim 1, wherein an incident angle αi at which is incident is αi = α (constant). In n LED rows arranged in the vertical direction, the incident angle at which the first reflected light of the straight LED light emitted from the lowermost LED (L1) enters the second reflecting mirror is β1, and the lowermost LED The incident angle at which the first reflected light of the straight LED light emitted from the i-th LED (Li) counted from (L1) is incident on the second reflecting mirror is βi, and the uppermost LED (i = n) When the incident angle at which the first reflected light of the emitted straight LED light is incident on the second reflecting mirror is βn,
The second reflecting mirror is a curved surface satisfying β1>...> Βi-1 <βi <βi + 1 <... <βn, and is a smooth and continuous (differentiable) curved surface. The LED lighting device according to any one of claims 1 to 4. The second reflecting mirror is a plane mirror, and LED straight light emitted from the LEDs (Li) (i = 1,..., I,..., N) in the n LED rows arranged in the vertical direction. The illumination apparatus according to claim 1, wherein an incident angle βi at which the first reflected light is incident on the second reflecting mirror is βi = β (constant). LED lighting device according to any one of claims 1 to 6, characterized in that 80 degrees <αi + βi <90 degrees, preferably 85 degrees <αi + βi <95 degrees, optimally αi + βi = 90 degrees. . The LED lighting device according to claim 1, wherein the second reflecting mirror is transparent glass or transparent plastic. The LED illumination device according to claim 8, wherein the first reflected light incident on the second reflecting mirror is totally reflected.