JP6846647B2 - Light source unit and lighting equipment equipped with it - Google Patents

Description

The present invention relates to a light source unit and a luminaire including the light source unit, and more particularly to a light source unit including a plurality of LEDs and a luminaire including the same.

Conventionally, a luminaire including a plurality of light source units has been provided (for example, Patent Document 1). Each of the plurality of light source units described in Patent Document 1 includes a rectangular flat plate-shaped light source having a light emitting surface on one surface, an instrument main body on which the light source is mounted, and an optical member that controls the light distribution of the light source. .. The light source has a plurality of LEDs arranged in a matrix. The optical member includes a plurality of rows of lens portions that control the light distribution of the plurality of LEDs for each row, and a connecting portion that connects the lens portions. The lens portion is formed in a band length shape along the row direction of the LEDs arranged in a matrix.

The lens unit connects the concave groove-shaped incident portion on which the light emitted from the LED is incident, the long-shaped emitting portion facing the incident portion, the incident portion and the emitting portion, and receives the light incident from the incident portion. It has a pair of reflective portions that totally reflect.

Japanese Unexamined Patent Publication No. 2016-058329

However, in the light source unit of Patent Document 1, a part of the light emitted from the light source and incident on the incident portion of the lens portion is emitted from a portion other than the emitting portion of the lens portion (for example, a lens portion adjacent to the lens portion). It may leak. Therefore, in the light source unit described in Patent Document 1 and the lighting equipment provided with the light source unit, it is desired to further suppress the emission of light in a direction other than the desired direction.

The present invention has been made in view of the above reasons, and an object of the present invention is to provide a light source unit capable of further suppressing the emission of light in a direction other than a desired direction, and a luminaire including the light source unit.

One aspect of the light source unit according to the present invention includes a light source and a reflecting member that is radiated from the light source and controls the distribution of light. The light source has a plurality of LEDs. The light source is arranged so that the plurality of LEDs are arranged in a plurality of rows. The reflective member has a plurality of through holes for exposing the plurality of LEDs for each group of LEDs in the plurality of rows when viewed from the front. The reflective member receives light emitted from each of the group of LEDs whose inner peripheral surfaces of the plurality of through holes in the reflective member are inside the inner peripheral surface when viewed from the front side of the reflective member. It has a first reflecting surface and a second reflecting surface that reflect toward the front side. The reflecting members face each other in a direction in which the first reflecting surface and the second reflecting surface are orthogonal to the direction in which the group of LEDs are arranged. The first reflective surface has a shape along a part of the first parabolic column surface. The second reflective surface has a shape along a part of the second parabolic column surface. The opening area of each of the plurality of through holes is larger toward the front side of the reflective member.
Another aspect of the light source unit according to the present invention includes a light source and a reflecting member that is radiated from the light source and controls the distribution of light. The light source has a plurality of LEDs. The light source is arranged so that the plurality of LEDs are arranged in a plurality of rows. The reflective member has a plurality of through holes for exposing the plurality of LEDs for each group of LEDs in the plurality of rows when viewed from the front. The reflective member receives light emitted from each of the group of LEDs whose inner peripheral surfaces of the plurality of through holes in the reflective member are inside the inner peripheral surface when viewed from the front side of the reflective member. It has a first reflecting surface and a second reflecting surface that reflect toward the front side. The reflecting members face each other in a direction in which the first reflecting surface and the second reflecting surface are orthogonal to the direction in which the group of LEDs are arranged. The second reflecting surface includes a portion configured to reflect the incident light radiated from the group of LEDs toward the first reflecting surface, and the incident light radiated from the group of LEDs. It has a portion configured to reflect to the front side of the reflective member.

One aspect of the luminaire according to the present invention includes the above-mentioned light source unit and a holding member for holding the light source unit.

The light source unit of the present invention and the lighting equipment provided with the light source unit have an effect that it is possible to further suppress the emission of light in a direction other than a desired direction.

FIG. 1 is a perspective view of a lighting fixture provided with a light source unit according to an embodiment of the present invention as viewed from the front side. FIG. 2 is a perspective view of a lighting fixture provided with the same light source unit as viewed from the rear side. FIG. 3 is an exploded perspective view of the same light source unit. FIG. 4A is a plan view of a main part of the light source unit of the same as above, FIG. 4B shows a main part of the light source unit of the same as above, and is a sectional view taken along line X1-X1 of FIG. 4A. FIG. 5 is a schematic view showing a path of light radiated from an LED in the light source of the light source unit of the above.

Hereinafter, the lighting fixture 10 according to the embodiment of the present invention will be described with reference to FIGS. 1 to 5. The luminaire 10 is, for example, a floodlight used as an apron luminaire in an airport. Therefore, the luminaire 10 is used by being attached to a mounting base provided on a pole, for example, at an airport.

As shown in FIGS. 1 and 2, the luminaire 10 supplies electric power to a plurality of (six in this case) light source units 1, a connecting member 2 for connecting the light source units 1 to each other, and a plurality of light source units 1. It includes a power supply unit 3. The luminaire 10 further includes a holding member 4 that holds a plurality of light source units 1, a connecting member 2, and a power supply unit 3. In the luminaire 10, as an example, three light source units 1 are arranged side by side in the horizontal direction and two light source units 1 are arranged side by side in the vertical direction.

As shown in FIG. 3, each of the six light source units 1 includes an LED module (light source) 6 and a heat radiating member 7 for dissipating heat generated by the LED module 6. The light source unit 1 further includes a heat conductive sheet 71 for efficiently transferring the heat generated by the LED module 6 to the heat radiating member 7, and a reflecting member 5 for controlling the light distribution of the light radiated from the LED module 6. .. The light source unit 1 is attached to the heat radiating member 7 so as to cover the fixing base 8 for fixing the reflecting member 5 and the LED module 6 to the heat radiating member 7, the reflecting member 5, the fixing base 8, and the LED module 6. A cover 9 that transmits light emitted from the LED module 6 is further provided.

The LED module 6 includes a substrate 61 having a first surface 611 and a second surface 612 that are opposite to each other in the thickness direction, and a plurality of (22 in this case) LEDs 62 mounted on the first surface 611 of the substrate 61. LED: Light Emitting Diode). The substrate 61 is formed in the shape of a rectangular plate. The substrate 61 is, for example, a metal-based printed wiring board. A circular insertion hole 63 is formed in the center of the substrate 61. The LED module 6 includes a pair of connectors 64 mounted on the first surface 611 of the substrate 61. The connector of the power cable connected to the power supply unit 3 is connected to the connector 64.

In the LED module, as shown in FIGS. 3 and 4, a plurality of LEDs 62 are arranged in a plurality of rows (here, 5 rows) on the first surface 611 of the substrate 61. In the LED module 6, a group (here, 4 or 5) of LEDs 62 are arranged in a straight line in each of the plurality of rows. Here, in the LED module 6, a plurality of LEDs 62 are staggered. In the following, for convenience of explanation, the direction orthogonal to the thickness direction of the substrate 61 and orthogonal to the direction in which the group of LEDs 62 are arranged is defined as the first direction L1, and is orthogonal to the thickness direction of the substrate 61 and the first direction. The direction orthogonal to L1 will be described as the second direction L2 (see FIGS. 3, 4A and 4B).

In the LED module 6, a group (4 or 5) LEDs 62 out of a plurality of LEDs 62 are arranged in a straight line in the second direction L2. Further, in the LED module 6, there are a plurality of rows of a group of LEDs 62 arranged in a straight line in the second direction L2, and they are lined up in the first direction L1. The optical axes OA1 (see FIG. 5) of each of the plurality of LEDs 62 are parallel to each other. The optical axis OA1 coincides with, for example, the thickness direction of the substrate 61, and is orthogonal to the first direction L1 and the second direction L2.

The heat conduction sheet 71 is a member for efficiently conducting the heat generated by the LED module 6 from the substrate 61 to the heat dissipation member 7. The heat conductive sheet 71 has electrical insulation and heat conductivity. The heat conductive sheet 71 is formed in the shape of a rectangular sheet. A circular insertion hole 711 is formed in the center of the heat conductive sheet 71. The inner diameter of the insertion hole 711 is smaller than the inner diameter of the insertion hole 63 of the substrate 61. The plane size of the heat conductive sheet 71 is preferably larger than the plane size of the substrate 61. The heat conductive sheet 71 is arranged so as to be interposed between the second surface 612 of the substrate 61 and the heat radiating member 7. In short, the heat conductive sheet is arranged so as to come into contact with the 71, the second surface 612 of the substrate 61, and the heat radiating member 7. The heat conductive sheet 71 is formed of, for example, an elastomer material. The heat conductive sheet 71 may be, for example, a silicone gel sheet or the like. Further, the material of the heat conductive sheet 71 is not limited to the elastomer material and the silicone gel, and may be, for example, an acrylic resin containing a filler.

As shown in FIG. 3, the heat radiating member 7 includes a rectangular plate-shaped base 72 in which the LED module 6 is arranged via the heat conductive sheet 71, and a plurality of heat radiating fins 73 integrally formed on the base 72. , Equipped with. The material of the heat radiating member 7 is, for example, an aluminum alloy. The base 72 has a first surface 721 and a second surface 722 that are opposite to each other in the thickness direction. In the heat radiating member 7, the heat conductive sheet 71 is arranged on the first surface 721 of the base 72. The plurality of heat radiation fins 73 project from the second surface 722 of the base 72.

In the light source unit 1, the LED module 6 is held between the fixed base 8 and the base 72 by attaching the fixed base 8 to the base 72 of the heat radiating member 7. The fixing base 8 is formed of a resin (for example, polybutylene terephthalate or the like). The fixing base 8 is interposed between the LED module 6 and the reflecting member 5. The fixing base 8 includes a frame portion 81, a flange 83, a holding portion 84, and a beam portion 82. The frame portion 81 is formed in a rectangular frame shape that surrounds the substrate 61 of the LED module 6 over the entire circumference. The frame portion 81 has a U-shape in cross section orthogonal to the circumferential direction thereof. Here, the frame portion 81 has a U-shape in which the heat conductive sheet 71 side is open with respect to a cross-sectional shape orthogonal to the circumferential direction thereof. In the light source unit 1, the peripheral portion of the heat conductive sheet 71 is interposed between the frame portion 81 and the base 72.

The flange 83 projects outward from the outer peripheral surface of the frame portion 81. The flange 83 has screw insertion portions 831 formed at each of the four corners. Further, the fixing base 8 has four recesses 832 formed so as to straddle the frame portion 81 and the flange 83. The four recesses 832 are separated from each other in the circumferential direction of the frame portion 81 and the flange 83. Two of the four recesses 832 are formed in each of the two first frame pieces 811 parallel to the first direction L1 of the frame portion 81. The recess 832 is configured to accommodate the legs 52 of the reflective member 5, which will be described later.

The pressing portion 84 projects from each of the two second frame pieces 812 parallel to the second direction L2 of the frame portion 81 toward the inside of the frame portion 81. The pressing portion 84 sandwiches the peripheral portion of the substrate 61 with the heat conductive sheet 71 on the base 72.

The beam portion 82 connects the central portions of the two first frame pieces 811 parallel to the first direction L1 of the frame portions 81. The beam portion 82 has a pair of beams 821 whose longitudinal direction is the second direction L2, and a connecting piece 820 that connects the central portions of the pair of beams 821 to each other. The communication piece 820 is formed with a circular insertion hole 822. Each of the pair of beams 821 is arranged so as not to be seen from the front side of the reflective member 5. More specifically, the pair of beams 821 are covered by the reflective member 5. The contact piece 820 has a pair of projecting pieces 823 protruding in the thickness direction of the contact piece 820. A pair of projecting pieces 823 are arranged on both sides of the insertion hole 822 in the second direction L2. The insertion hole 822 is connected to the insertion hole 63 of the substrate 61 in the LED module 6. In the light source unit 1, the shaft portion of the bolt inserted into the insertion hole 822 of the fixing base 8 is fixed to the base 72 through the insertion hole 63 of the substrate 61 in the LED module 6 and the insertion hole 711 of the heat conductive sheet 71. There is.

The cover 9 that covers the LED module 6 and the reflective member 5 and the like includes a cover main body 91, a flange portion 92, and four pressing plates 93. The cover body 91 and the collar portion 92 are integrally formed of a translucent resin material such as polycarbonate resin. The cover body 91 is formed in a rectangular box shape with one side open. The collar portion 92 projects outward from the peripheral edge of the opening surface of the cover main body 91 over the entire circumference. The collar portion 92 is formed in a rectangular frame shape. Circular holes 921 are formed at each of the four corners of the collar portion 92. A plurality of screw insertion holes are formed in the flange portion 92 so as to be separated from each other in the circumferential direction of the collar portion 92. The cover 9 is fixed to the heat radiating member 7 so that the bottom wall 911 of the cover main body 91 faces the plurality of LEDs 62.

Each of the four presser plates 93 is formed of a metal plate, for example, a stainless steel plate. Each of the four presser plates 93 has a base portion 931 and a side portion 932. The base portion 931 and the side portion 932 are integrally formed. The base 931 is formed in the shape of a long plate. The base 931 is formed with screw insertion holes at the center and both ends in the longitudinal direction. The side portion 932 projects from one end edge along the longitudinal direction of the base portion 931 in a direction intersecting the base portion 931. The four holding plates 93 are overlapped with the flange portion 92 of the cover 9. A screw 933 is inserted into each of the screw insertion holes of the four holding plates 93. The screw 933 is fitted into the base 72 through the screw insertion hole of the flange portion 92.

The light distribution of the light emitted from the LED module 6 is controlled by the reflecting member 5. As shown in FIGS. 3 and 4, the reflective member 5 includes a reflective member main body 50 and four legs 52. The reflective member 5 is attached to the heat radiating member 7 by screwing the cover 9 to the heat radiating member 7. Details of the reflective member 5 will be described later.

By the way, in the luminaire 10, three light source units 1 are arranged side by side in the horizontal direction. Further, in the luminaire 10, two light source units 1 are arranged side by side in the vertical direction. In other words, in the luminaire 10, the six light source units 1 are divided into three side-by-side three light source units 1 and arranged in two rows.

Here, the luminaire 10 includes a connecting member 2 for connecting the six light source units 1 to each other. As shown in FIG. 1, the connecting member 2 includes a pair of first connecting members 21 and a pair of second connecting members 22.

The pair of first connecting members 21 connect three light source units 1 arranged in the horizontal direction. The pair of first connecting members 21 are formed of a metal plate, for example, a stainless steel plate. The pair of first connecting members 21 has a long base portion 211 and side plates 212 extending in the thickness direction of the base portion 211 along the longitudinal direction of the base portion 211. The base portion 211 and the side plate 212 are integrally formed. Each base 211 of the first connecting member 21 is provided with a plurality of screw insertion holes separated in the longitudinal direction of the base 211. The pair of first connecting members 21 are arranged in the horizontal direction by screwing the screws inserted into the screw insertion holes to the heat radiating members 7 of the light source unit 1 in which the screws are arranged in the horizontal direction. The light source unit 1 is connected.

The pair of second connecting members 22 connect two light source units 1 arranged in the vertical direction on both sides of the lighting fixture 10 in the horizontal direction. The pair of second connecting members 22 are formed of a metal plate, for example, a stainless steel plate. Each of the pair of second connecting members 22 is formed in the shape of a long plate. Each of the pair of second connecting members 22 has a step between each of both ends in the longitudinal direction and the central portion. Each of the pair of second connecting members 22 is formed so that the central portion protrudes in the thickness direction of both ends with respect to both ends. Each of the pair of second connecting members 22 is provided with screw insertion holes at both ends in the longitudinal direction and at the center. Each of the pair of second connecting members 22 is screwed to the heat radiation member 7 of the upper light source unit 1 of the two light source units 1 having one of both ends arranged in the vertical direction, and the other is screwed to the lower light source unit 1. It is screwed to the heat radiating member 7 of. As a result, each of the pair of second connecting members 22 connects two light source units 1 arranged in the vertical direction.

The power supply unit 3 that supplies electric power to the six light source units 1 includes, for example, two power supply devices 31 and 32. The power supply unit 3 is configured so that a power cable drawn from the outside and a power cable electrically connected to the six light source units 1 can be connected.

AC voltage is supplied to the power supply devices 31 and 32 from an external power source, for example, a commercial power source. The power supply devices 31 and 32 include a rectifying and smoothing circuit that converts the supplied AC voltage into a DC voltage, a DC-DC converter that converts the DC voltage output from the rectifying and smoothing circuit into a DC voltage having a predetermined voltage value, and the like. ..

The luminaire 10 further includes a holding member 4 that holds the six light source units 1. The holding member 4 is attached to a mounting base provided on a pole at an airport or the like. The holding member 4 is configured so that the direction of the light source unit 1 can be changed. As shown in FIG. 2, the holding member 4 includes a pair of holding portions 41, a pair of mounting members 42, a fixing plate 43, a pair of arms 44, and a scale portion 45.

Each of the pair of holding portions 41 is made of metal, for example, stainless steel. The pair of holding portions 41 are provided at both ends in the lateral direction of the luminaire 10. The pair of holding portions 41 are arranged between the pair of mounting members 42 and the second connecting member 22 in order to connect the pair of mounting members 42 to the second connecting member 22. Further, each of the pair of holding portions 41 is provided with a screw hole into which a screw for attaching a one-to-one corresponding arm 44 of the pair of arms 44 is fitted.

The pair of mounting members 42 are formed of a metal plate, for example, a stainless steel plate. The pair of mounting members 42 are formed in a long plate shape. The power supply unit 3 is attached to the pair of attachment members 42 by being screwed or the like.

The fixing plate 43 is fixed to a mounting base provided on the pole. The fixing plate 43 is formed in a trapezoidal plate shape. The fixing plate 43 and the pair of arms 44 are integrally formed. A circular insertion hole 431 through which a bolt is inserted is formed in the center of the fixing plate 43. The fixing plate 43 is formed with a semicircular long hole 432 centered on the insertion hole 431. Bolts are inserted into each of the insertion holes 431 and the elongated holes 432 of the fixing plate 43. The fixing plate 43 is rotatable around a bolt inserted through the insertion hole 431.

A screw insertion hole 441 through which a screw is inserted is formed at the tip of the pair of arms 44. The screw insertion holes 441 of the pair of arms 44 are connected to the screw holes of the holding portion 41 corresponding to one-to-one among the pair of holding portions 41. The screw inserted through the screw insertion hole 441 is fitted into the screw hole of the holding portion 41. In this way, the pair of arms 44 are held by each of the pair of holding portions 41. By loosening the screw inserted into the screw insertion hole 441, the holding portion 41 can rotate around the screw.

The scale portion 45 is formed of a metal plate, for example, a stainless steel plate. The scale portion 45 is formed in a disk shape. The scale portion 45 is attached to one of the pair of arms 44. The scale portion 45 is engraved with a scale having an angle centered on the bolt inserted into the screw insertion hole 441. The scale portion 45 allows a person to visually recognize the rotation angle from the reference position when the six light source units 1 connected to the arm 44 are rotated around the bolt of the screw insertion hole 441 of the holding portion 41. It is configured in. As a result, in the luminaire 10, a person can accurately adjust the inclination of the light source unit 1. The rotation angle from the reference position is the same as the angle formed by the front direction of the light source unit 1 with respect to the plane (horizontal plane) parallel to the fixed plate 43.

Here, the reflecting member 5 that controls the light distribution of the light emitted from the LED module 6 will be described with reference to FIGS. 3 and 4.

Each of the reflective members 5 has a plurality (5) through holes 510 that expose a group (4 or 5) of LEDs 62. The reflective member 5 includes a resin molded body and a metal film provided on a part of the surface of the resin molded body. In the reflective member 5, the surface of the metal film includes the first reflective surface 511 and the second reflective surface 512, which will be described later. The metal film is, for example, an aluminum film. The metal film is formed by, for example, a thin-film deposition method. The opening shape of each of the plurality (five) through holes 510 is rectangular with the second direction L2 as the longitudinal direction so as to expose the plurality of LEDs 62. The plurality of through holes 510 are arranged at substantially equal intervals in the first direction L1. The reflecting member 5 has a first reflecting surface 511 and a second reflecting surface 512, each of which forms a part of the inner peripheral surface of the through hole 510, in each of the plurality of through holes 510. The first reflecting surface 511 and the second reflecting surface 512 face each other in the first direction L1. Here, the reflective member 5 has an opening area of each of the plurality of through holes 510 increasing as the distance from the substrate 61 increases in the thickness direction of the substrate 61. The reflective member 5 includes a reflective member main body 50 and legs 52. In the reflective member 5, the first reflective surface 511 in which the reflective member main body 50 has the plurality of through holes 510 described above is a parabola in a direction orthogonal to the second direction L2 (hereinafter, referred to as “first parabola”). Is formed in a shape along a part of a parabolic column surface (hereinafter, referred to as "first parabolic column surface") formed by sweeping in the second direction L2. A first parabola corresponding to the first reflecting surface 511 in Cartesian coordinates with the center of the light emitting surface of the LED 62 as the origin, defining the x-axis along the first direction L1 and the y-axis along the optical axis OA1 of the LED 62. The first parabola for defining the pillar surface can be expressed by the mathematical formula of _{y = a 1} × x ² + b ₁ × x + c _1. In this formula, a ₁ , b ₁ , and c ₁ represent coefficients.

The second reflecting surface 512 is a parabola surface (hereinafter, "second parabola") formed by sweeping a parabola in a direction orthogonal to the second direction L2 (hereinafter, referred to as "second parabola") in the second direction L2. It is formed in a shape along a part of the "pillar surface"). The second parabola for defining the second parabola corresponding to the second reflecting surface 512 in the above-mentioned Cartesian coordinates can be expressed by the mathematical formula of _{y = a 2} × x ² + b ₂ × x + c _2. In this formula, a ₂ , b ₂ , and c ₂ represent coefficients. _{The value of the coefficient a 1 and} the value of the coefficient a ₂ are different between the first parabola corresponding to the first reflecting surface 511 and the second parabola corresponding to the second reflecting surface 512, but the value is not limited to this and may be the same. .. _{Further, the value of the coefficient b 1 and} the value of the coefficient b ₂ are different between the first parabola and the second parabola, but the value is not limited to this and may be the same. _{Further, the value of the coefficient c 1 and} the value of the coefficient c ₂ are different between the first parabola and the second parabola, but the value is not limited to this and may be the same. Each axis of the first parabola and the second parabola is tilted with respect to the optical axis OA1 of the LED 62. Here, a ₂ > a ₁ .

The reflecting member 5 includes a third reflecting surface 513 and a fourth reflecting surface 514 in which the inner peripheral surfaces of the plurality of through holes 510 intersect with the first direction L1. The third reflecting surface 513 and the fourth reflecting surface 514 reflect the incident light radiated from the group of LEDs 62 to the front side of the reflecting member 5.

Each of the four legs 52 is configured to be fitted into the recess 832 of the fixing base 8. The four leg portions 52 include a main body portion 521 formed in a plate shape and a protruding portion 522. The main body portion 521 and the protruding portion 522 are integrally formed. The main body 521 is formed in a plate shape. The protruding portion 522 projects outward in the thickness direction of the main body portion 521. A screw insertion portion 523 through which a screw is inserted is formed in the protrusion 522.

Here, the path of the light radiated from the LED 62 of the LED module 6 will be described with reference to FIG.

The path of the light radiated from the LED 62 toward the second reflecting surface 512 will be described. The light emitted from the LED 62 toward the second reflecting surface 512 and incident on a portion of the plurality of reflecting surfaces of the second reflecting surface 512 that is relatively close to the LED 62 is the light emitted at the portion. 1 Reflected toward the reflecting surface 511. The path of this light is shown by the dotted line OP1 in FIG. Light emitted from the LED 62 toward the second reflecting surface 512 and incident on a portion of the number of reflecting surfaces of the second reflecting surface 512 that is relatively far from the LED 62 is reflected at the portion. Then, the light is emitted from the opening on the front side of the reflective member 5. The route ahead is shown by the alternate long and short dash line OP3 in FIG. In short, the second reflecting surface 512 reflects the light radiated from the LED 62 and incident on a portion relatively far from the LED 62 toward the front side of the reflecting member 5. The second parabolic surface 512 is defined by the above-mentioned second parabola in order to achieve different reflection characteristics between the portion relatively close to the LED 62 and the portion far from the LED 62 as described above. Is rotated or moved as appropriate. Further, the reflecting member 5 sets the height of one of the second reflecting surfaces 512 of the first direction L1 among the plurality of (five) second reflecting surfaces 512 to be higher than the height of the other four second reflecting surfaces 512. Is also lowered so that one of the second reflecting surfaces 512 is on the lower side and the other second reflecting surface 512 is on the upper side. That is, although the reflection member 5 is not shown in the light source unit 1 shown in FIG. 1, the reflection member 5 in FIG. 4A has the right side of FIG. 4A on the upper side of FIG. 1 and the left side of FIG. 4A on the lower side of FIG. It is arranged so as to be.

The path of the light radiated from the LED 62 toward the first reflecting surface 511 will be described. The path of the light radiated from the LED 62 toward the first reflecting surface 511 is shown by the broken line OP2 in FIG. The first reflecting surface 511 reflects the incident light radiated from the LED 62 toward the front side of the reflecting member 5. The first reflecting surface 511 appropriately rotates the first parabola surface defined by the above-mentioned first parabola in order to achieve different reflection characteristics in the portion relatively close to the LED 62 and the portion far away from the LED 62. Or moved.

The path of the light radiated from the LED 62 toward the front side of the reflecting member 5 will be described. The paths of the light radiated from the LED 62 toward the front side of the reflecting member 5 are shown by solid lines OP4 and OP5 in FIG. A part of the light emitted from the LED 62 is emitted toward the front side of the reflecting member 5. That is, the path of the light emitted from the LED 62 that is not reflected by either the first reflecting surface 511 or the second reflecting surface 512 is formed between the solid line OP4 and the solid line OP5 in the first direction L1. .. As a result, the light source unit 1 can suppress the emission of a place other than the illumination target.

Further, the light source unit 1 suppresses the emission of light to a place other than the irradiation target by reflecting the light emitted from the LED 62 and incident on the second reflecting surface 512 toward the first reflecting surface 511. Is possible.

As shown in FIGS. 1 and 2, the luminaire 10 includes six light source units 1, but is not limited to this, and may include at least one light source unit 1, for example, two light source units. A configuration including 1 and a configuration including 4 light source units 1 may be used.

The light source unit 1 of the present embodiment includes an LED module (light source) 6 and a reflecting member 5 that controls the distribution of light emitted from the LED module 6. The LED module 6 has a plurality of LEDs 62. The LED module 6 is arranged so that a plurality of LEDs 62 are arranged in a plurality of rows. The reflective member 5 has a plurality of through holes 510 for exposing the plurality of LEDs 62 for each group of LEDs in a plurality of rows when viewed from the front. The inner peripheral surface of each of the plurality of through holes 510 in the reflective member 5 reflects the light radiated from each of the group of LEDs 62 inside the inner peripheral surface when viewed from the front side of the reflective member 5 to the front side. It has one reflecting surface 511 and a second reflecting surface 512. In the reflective member 5, the first reflective surface 511 and the second reflective surface 512 face each other in a direction orthogonal to the direction in which the group of LEDs 62 are arranged. As a result, the light source unit 1 can further suppress the emission of light in a direction other than the desired direction.

In the light source unit 1 of the present embodiment, it is preferable that the second reflecting surface 512 includes a portion configured to reflect the incident light radiated from the group of LEDs 62 toward the first reflecting surface 511. The second reflecting surface 512 preferably includes a portion configured to reflect the incident light radiated from the group of LEDs 62 to the front side of the reflecting member 5. As a result, the light source unit 1 can further suppress the emission of light in a direction other than the desired direction.

In the light source unit 1 of the present embodiment, the reflection member 5 has a third reflection surface 513 and a fourth reflection surface 514 in which the inner peripheral surfaces of the plurality of through holes 510 intersect in the direction in which they are aligned with the group of LEDs 62. Is preferable. The third reflecting surface 513 and the fourth reflecting surface 514 are preferably configured to reflect the incident light radiated from the group of LEDs 62 to the front side of the reflecting member 5. As a result, the light source unit 1 can further suppress the emission of light in a direction other than the desired direction.

The luminaire 10 of the present embodiment includes a light source unit 1 and a holding member 4 for holding the light source unit 1. As a result, the luminaire 10 can further suppress the emission of light in a direction other than the desired direction.

1 Light source unit 10 Lighting equipment 4 Holding member 5 Reflective member 510 Through hole 511 1st reflective surface 512 2nd reflective surface 513 3rd reflective surface 514 4th reflective surface 6 LED module (light source)
62 LED
OA1 optical axis OP1, OP2 optical path

Claims (4)

A light source and a reflecting member that controls the distribution of light emitted from the light source are provided.
The light source has a plurality of LEDs, and the plurality of LEDs are arranged so as to be arranged in a plurality of rows.
The reflective member has a plurality of through holes for exposing the plurality of LEDs for each group of LEDs in the plurality of rows when viewed from the front.
The inner peripheral surface of each of the plurality of through holes in the reflective member reflects the light radiated from each of the group of LEDs inside the inner peripheral surface when viewed from the front side of the reflective member. It has a first reflective surface and a second reflective surface,
The first reflecting surface and the second reflecting surface face each other in a direction orthogonal to the direction in which the group of LEDs are arranged .
The first reflective surface has a shape along a part of the first parabolic column surface.
The second reflective surface has a shape along a part of the second parabolic column surface.
The opening area of each of the plurality of through holes is larger toward the front side of the reflective member .
A light source unit characterized by that. A light source and a reflecting member that controls the distribution of light emitted from the light source are provided.
The light source has a plurality of LEDs, and the plurality of LEDs are arranged so as to be arranged in a plurality of rows.
The reflective member has a plurality of through holes for exposing the plurality of LEDs for each group of LEDs in the plurality of rows when viewed from the front.
The inner peripheral surface of each of the plurality of through holes in the reflective member reflects the light radiated from each of the group of LEDs inside the inner peripheral surface when viewed from the front side of the reflective member. It has a first reflective surface and a second reflective surface,
The first reflecting surface and the second reflecting surface face each other in a direction orthogonal to the direction in which the group of LEDs are arranged.
The second reflecting surface includes a portion configured to reflect the incident light radiated from the group of LEDs toward the first reflecting surface.
Having a portion configured to reflection of light incident radiated to the front side of the reflective member from the group of LED,
Light source unit you wherein a. The reflecting member has a third reflecting surface and a fourth reflecting surface in which the inner peripheral surfaces of the plurality of through holes intersect in a direction in which the inner peripheral surfaces of the plurality of through holes intersect with the group of LEDs.
The third reflecting surface and the fourth reflecting surface are configured to reflect the incident light radiated from the group of LEDs to the front side of the reflecting member.
The light source unit according to claim 1 or 2. The light source unit according to any one of claims 1 to 3 and a holding member for holding the light source unit.
Lighting equipment that is characterized by that.

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