JP2016051649A - lighting equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting apparatus having a relatively simple structure and higher reliability.SOLUTION: A lighting apparatus 200 includes a light source unit 1, and a holding part 9 holding the light source unit 1 at a predetermined angle with respect to a mount face 9aa. The light source unit 1 includes a mount substrate 21 on which a solid light-emitting element is mounted, and a heat radiation member 3 mounted with the mount substrate 21 and radiating heat emitted from the solid light-emitting element. The heat radiation member 3 includes a base part on which the mount substrate 21 is mounted, and a heat radiation plate 32. The heat radiation plate 32 protrudes from a second face opposite to a first face of the base part on which the mount substrate 21 is mounted. The heat radiation plate 32 has planar profile. The plural heat radiation plates 32 arranged in parallel are provided in the base part. A tip end portion 32a of the heat radiation plate 32 is decreased in a thickness dimension toward the tip.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a lighting fixture, and more particularly to a lighting fixture that uses a solid-state light emitting element as a light source.

  In recent years, lighting fixtures using a solid light emitting element such as a light emitting diode as a light source have been used. Hereinafter, the light emitting diode is also referred to as an LED (light emitting diode).

  This kind of lighting fixture is provided with the light source unit which has the LED mounting substrate in which several LED was mounted, and the thermal radiation part which thermally radiates the heat which arises from LED (for example, refer patent document 1).

  In Patent Document 1, in a state where the lighting device is installed on the ceiling surface, a heat radiation fin as a heat radiation portion is provided in a space formed between the light source unit and the ceiling surface. In patent document 1, the bird intrusion prevention means which prevents that birds fly in the space formed between the light source unit and the ceiling surface is provided. Patent Document 1 describes that heat can be efficiently dissipated in a state where the lighting device is installed on the ceiling surface, and deterioration of appearance and corrosion of components caused by bird dropping can be suppressed.

JP 2014-78329 A

  By the way, lighting fixtures are installed not only when installed on the ceiling surface but also at various places such as a projector stand in stadium lighting by providing a holding unit that holds the light source unit at a predetermined angle with respect to the installation surface. It is possible to make it possible. In the case where the lighting fixture cannot include a bird intrusion prevention means between the ceiling surface and the ceiling surface, there is a possibility that the heat radiation performance of the heat radiation fin as a heat radiation plate is lowered and the reliability of the LED is deteriorated due to bird dropping. is there.

  Therefore, the lighting fixture is required to have a relatively simple configuration and a more reliable configuration, and the configuration of the above-described Patent Document 1 is not sufficient, and further improvement is required.

  This invention is made | formed in view of the said reason, The objective is to provide a more reliable lighting fixture with a comparatively simple structure.

  The lighting fixture of this invention is equipped with the light source unit and the holding | maintenance part. The light source unit includes a solid light emitting element, a mounting substrate, and a heat dissipation member. The mounting substrate is mounted with the solid state light emitting device. The heat dissipation member mounts the mounting board. The heat dissipation member is configured to dissipate heat generated by the solid state light emitting device. The holding unit is configured to hold the light source unit at a predetermined angle with respect to the installation surface. The said heat radiating member has a base part and a heat sink. The base portion is configured so that the mounting board can be mounted thereon. The heat sink protrudes from a second surface opposite to the first surface on which the mounting substrate of the base portion is mounted. The heat sink has a plate-like outer shape. A plurality of the heat radiating plates arranged in parallel are arranged on the base portion. The tip of the heat sink has a thickness dimension that decreases toward the tip.

  The lighting fixture of the present invention has an effect that the reliability can be further enhanced with a relatively simple configuration.

It is a perspective view which shows the lighting fixture of embodiment. It is a left view which shows the lighting fixture of embodiment. It is a front view which shows the lighting fixture of embodiment. It is the rear view which abbreviate | omitted some lighting fixtures of embodiment. It is a perspective view of the back side explaining the principal part of the lighting fixture of embodiment. It is a disassembled perspective view which shows the light source unit used for the lighting fixture of embodiment. It is a front view which shows the other principal part of the lighting fixture of embodiment. It is a rear view which shows the other principal part of the lighting fixture of embodiment. It is a top view which shows the other principal part of the lighting fixture of embodiment. It is a left view which shows the other principal part of the lighting fixture of embodiment. It is a top view which shows another principal part of the lighting fixture of embodiment. It is a top view which shows the principal part of the modification 1 of the lighting fixture of embodiment. It is a top view which shows the principal part of the modification 2 of the lighting fixture of embodiment. It is a top view which shows the principal part of the modification 3 of the lighting fixture of embodiment. It is a top view which shows the principal part of the modification 4 of the lighting fixture of embodiment. It is a front view which shows another principal part of the lighting fixture of embodiment. It is a rear view which shows another principal part of the lighting fixture of embodiment. It is a side view which shows another principal part of the lighting fixture of embodiment. It is a front view which shows another principal part of the lighting fixture of embodiment. It is a rear view which shows another principal part of the lighting fixture of embodiment. It is a side view which shows another principal part of the lighting fixture of embodiment.

  Below, the lighting fixture 200 of this embodiment is demonstrated, referring FIG. 1 thru | or FIG. 5, and the light source unit 1 used for the lighting fixture 200 and the lighting fixture 200 is demonstrated referring FIG. 6 thru | or FIG. In the figure, the same members are denoted by the same reference numerals and redundant description is omitted. The size and positional relationship of the members shown in each drawing may be exaggerated for clarity of explanation. In the following description, each element constituting the present embodiment may be configured such that a plurality of elements are constituted by one member and the plurality of elements are shared by one member, and the function of one member is plural. You may implement | achieve by sharing with a member.

  The lighting fixture 200 of this embodiment is provided with the light source unit 1 and the holding | maintenance part 9, as shown in FIG. As shown in FIG. 6, the light source unit 1 includes an LED 20 that is a solid light emitting element, a mounting substrate 21, and a heat dissipation member 3. The LED 20 is mounted on the mounting substrate 21. The heat dissipation member 3 has a mounting substrate 21 mounted thereon. The heat radiating member 3 is configured to be able to radiate heat generated by the LED 20. The holding unit 9 is configured to hold the light source unit 1 at a predetermined angle with respect to the installation surface 9aa. The heat radiating member 3 has a base portion 30 and a heat radiating plate 32. The base portion 30 is configured so that the mounting substrate 21 can be mounted. As shown in FIGS. 7 to 10, the heat radiating plate 32 protrudes from a second surface 30ab opposite to the first surface 30aa on which the mounting substrate 21 of the base portion 30 is mounted. The heat sink 32 has a plate-like outer shape. A plurality of heat radiating plates 32 arranged in parallel are arranged on the base portion 30. As shown in FIG. 11, the front end portion 32a of the heat radiating plate 32 is reduced in thickness toward the front end.

  The lighting apparatus 200 of the present embodiment has a relatively simple configuration in which the distal end portion 32a of the heat radiating plate 32 has a thickness dimension that decreases toward the distal end, making it difficult for birds to stop and reliability associated with fecal damage of birds. It is possible to suppress the decrease.

  Initially, the light source unit 1 used for the lighting fixture 200 of this embodiment is demonstrated.

  As shown in FIG. 6, the light source unit 1 includes an LED module 2 and a heat dissipation member 3. Furthermore, the light source unit 1 includes a lens block 4, an attachment member 5, a heat conductive sheet 6, and a cover block 7.

  The LED module 2 constitutes a light source unit of the light source unit 1. The LED module 2 includes an LED 20 and a mounting substrate 21. The LED 20 includes, for example, an LED chip including a nitride semiconductor capable of emitting blue light in a light emitting layer and a phosphor that absorbs blue light emitted from the LED chip and emits yellow light in a package. It can be a structure. The LED 20 can emit white light by mixing the blue light emitted from the LED chip and the yellow light from the phosphor.

  The mounting substrate 21 can be formed using, for example, a metal base printed wiring board. The mounting substrate 21 can be, for example, a rectangular flat plate. The mounting substrate 21 is provided in the center so that the circular first hole 210 passes therethrough. The mounting substrate 21 is not limited to a rectangular shape, and may be circular or elliptical. The mounting substrate 21 has a plurality of LEDs 20 arranged in a two-dimensional array on the mounting surface. The mounting substrate 21 has a receptacle connector 22 mounted thereon. The receptacle connector 22 is electrically connected to the LED 20 via a wiring conductor formed on the mounting substrate 21. The mounting substrate 21 may be appropriately mounted with not only the LED 20 and the receptacle connector 22 but also a Zener diode that electrically protects the LED 20 and a driving element that drives the LED 20. As a material of the mounting substrate 21, a metal material such as aluminum that is superior in heat dissipation compared with a resin can be mainly used. The mounting substrate 21 is not limited to a metal base printed wiring board, and may be formed using, for example, a ceramic substrate.

  As shown in FIGS. 6 to 10, the heat radiating member 3 includes a base portion 30, a heat radiating plate 32, and an edge portion 31. The heat radiating member 3 can integrally form the base part 30, the edge part 31, and the heat radiating plate 32, for example with a metal material. As a material of the heat radiating member 3, for example, a metal material having excellent thermal conductivity such as an aluminum alloy or a copper alloy can be used.

  The base part 30 has a rectangular flat plate-like outer shape. The base portion 30 is provided with a plurality of first screw holes 300 on the first surface 30aa on which the LED module 2 is mounted. The first screw hole 300 constitutes a female screw. The base portion 30 is provided with a first insertion hole 301 penetrating in the thickness direction at a corner portion of the first surface 30aa. A cable gland 33 is attached to the first insertion hole 301. The cable gland 33 includes a cable gland main body 33a, a cap 33b covering the cable gland main body 33a, and a mounting screw 33c for attaching the cable gland main body 33a and the cap 33b to the base portion 30. The power supply line 23 shown in FIGS. 1 to 5 is inserted into the base portion 30 via a cable gland 33. The cable gland 33 is configured so that the inserted feeder line 23 can be tightened. The power supply line 23 is used to supply power to the LED module 2.

  As shown in FIG. 8, the edge portion 31 is provided along the side of the base portion 30 that is rectangular in plan view. Two edge portions 31 are provided. The two edge portions 31 are arranged to face each other with the base portion 30 interposed therebetween. The edge portion 31 has a rectangular parallelepiped shape, and is formed integrally with the base portion 30 at the end edge of the base portion 30. The edge portion 31 preferably includes a first coupling portion 312 coupled to another member along the thickness direction of the base portion 30. The first coupling portion 312 is configured by a second screw hole. The second screw hole is a female screw. Two first coupling portions 312 are provided so as to be aligned along the longitudinal direction of the edge portion 31. As shown in FIG. 9, the edge portion 31 is formed to be larger than the thickness dimension of the base portion 30 in the thickness direction of the base portion 30. The heat dissipating member 3 includes a groove 34. The groove portion 34 includes an edge portion 31, a heat radiating plate 32 adjacent to the edge portion 31, and a base portion 30 between the adjacent edge portion 31 and the heat radiating plate 32. It is preferable that the edge part 31 is provided with the 2nd coupling | bond part 310 couple | bonded with another member in the 1st direction along the longitudinal direction of the edge part 31 orthogonal to the thickness direction of the base part 30. FIG. The second coupling part 310 is configured by a third screw hole. The third screw hole is a female screw. One second coupling portion 310 is provided on each end surface of the edge portion 31 in the longitudinal direction. As shown in FIG. 10, the edge portion 31 preferably includes a third coupling portion 311 coupled to another member from a second direction orthogonal to the thickness direction of the base portion 30 and the first direction. The 3rd coupling part 311 is comprised by the 4th screw hole which penetrates the edge part 31 in a transversal direction. The fourth screw hole is a female screw. A plurality of third coupling portions 311 are provided at predetermined intervals along the longitudinal direction of the edge portion 31.

  The heat sink 32 protrudes from the second surface 30ab of the base portion 30. The heat radiating plate 32 can be formed in a rectangular flat plate shape. A plurality of the heat radiating plates 32 are provided on the base portion 30 at predetermined intervals so that the heat generated by the LEDs 20 can be efficiently radiated. The plurality of heat radiating plates 32 may be arranged on the base portion 30 at equal intervals, or the adjacent heat radiating plates 32 may be arranged at different intervals. The heat radiating plate 32 is formed in a tapered shape so that the thickness of the heat radiating plate 32 is reduced at the tip portion 32 a opposite to the base portion 30. In other words, the distal end portion 32a of the heat radiating plate 32 is reduced in thickness toward the distal end.

  By the way, in the lighting fixture provided with the light source unit 1, with the improvement of the light output of LED20, it has begun to be used not only for general lighting but also for a projector used in road lights, stadiums, and the like. The LED 20 has a characteristic that the light emission efficiency decreases due to heat generation. Further, the LED 20 tends to have a shorter life as the temperature rises due to heat generation. In the lighting fixture, the mounting substrate 21 on which the LEDs 20 are mounted has a heat radiation plate 32 mounted on the first surface 30aa of the base portion 30 of the heat dissipation member 3 and protruding from the second surface 30ab opposite to the first surface 30aa. Thus, the heat generated by the LED 20 can be efficiently radiated. In a lighting fixture such as a projector, the angle of the optical axis of the light source unit 1 with the direction along the horizontal plane is set to 0 °. For example, the light fixture unit 1 is often used to face downward in the vertical direction at an angle of 30 ° to 40 °. . Since the light emitting surface of the lighting fixture faces downward in the vertical direction, birds tend to stop on the heat radiating plate 32 provided on the side opposite to the light emitting surface. In the lighting fixture, if birds easily stop on the heat radiating plate 32, there is a possibility that the influence of bird droppings may increase. In particular, lighting fixtures are often installed at relatively high positions where it is difficult to perform maintenance and cleaning when used as floodlights. Compared to the case of installing lighting fixtures on the ground, There is a risk that the effects of fecal harm will be even greater. In the luminaire, in order to prevent birds from stopping on the heat radiating plate 32, it is conceivable to provide another part such as a net covering the entire back side of the luminaire on which the heat radiating plate 32 is provided, but the structure is complicated. Tend to be.

  In lighting fixture 200 of this embodiment, as shown in Drawing 11 thru / or Drawing 15, it can control that birds stop by making the shape of heat sink 32 itself into the specific shape where tip part 32a tapers. It is possible. As shown in FIG. 11, the heat radiating plate 32 of the luminaire 200 can have a shape in which a rectangular corner portion at the tip end portion 32 a is rounded in the thickness direction. In other words, the heat radiating plate 32 can have a round shape in which a corner of the tip is rounded. The lighting fixture 200 has a rounded shape at the tip end portion 32a, thereby improving the user-friendliness when assembling and installing the lighting fixture 200 and adjusting the angle of the light source unit 1 with respect to the installation surface 9aa. Can do.

  The heat radiating plate 32 in the lighting fixture 200 of Modification 1 shown in FIG. 12 has a shape having an edge on one side of the plate-shaped heat radiating plate 32. The lighting fixture 200 of the modification 1 can form the heat sink 32 more easily by setting it as the shape provided with the edge on the single side | surface side of the heat sink 32. FIG. The heat sink 32 in the lighting fixture 200 of the modification 2 shown in FIG. 13 has a shape in which the protruding direction with respect to the base portion 30 is inclined with respect to the second surface 30ab. The lighting fixture 200 of the modification 2 can make it more difficult for birds to balance and stop in the front-end | tip part 32a of the heat sink 32 because the protrusion direction of the heat sink 32 inclines.

  The heat sink 32 in the lighting fixture 200 of the modification 3 shown in FIG. 14 is provided with the protrusion piece 35 which protrudes along the 2nd surface 30ab and the parallel direction in the front-end | tip part 32a. The lighting fixture 200 of the modified example 3 is provided with the protruding piece 35, thereby suppressing the entry of foreign matter such as bird droppings between the adjacent heat sinks 32, thereby suppressing a decrease in heat dissipation performance. Is possible. In other words, the protruding piece 35 can function as a foreign matter entry suppression piece that inhibits foreign matter from entering the space surrounded by the adjacent heat radiating plate 32 and the base portion 30. The protruding piece 35 can be formed in a flat outer shape. The protruding piece 35 is provided in a direction approaching the adjacent heat radiating plate 32. The protruding piece 35 may be formed integrally with the heat radiating plate 32 or may be formed separately from the heat radiating plate 32. When the heat radiating plate 32 and the protruding piece 35 are formed separately, the lighting fixture 200 can fix the protruding piece 35 to the heat radiating plate 32 with screws or the like.

  The plurality of radiator plates 32 in the lighting fixture 200 of Modification 4 shown in FIG. 15 have different lengths from the base portion 30 to the tip in the adjacent radiator plates 32 among the plurality of radiator plates 32. The lighting fixture 200 of the modification 4 makes it more difficult for birds to balance and stop at the front-end | tip part 32a of the heat sink 32 because the adjacent heat sink 32 differs from the base part 30 in length. Can do. The luminaire 200 may have a structure in which not only the configuration of the heat dissipation plate 32 shown in the modification but also the configuration of the heat dissipation plate 32 described above is appropriately combined. The heat radiating plate 32 is not limited to the projecting direction projecting from the second surface 30ab of the base portion 30, and the thickness dimension may be reduced toward the tip in the direction perpendicular to the projecting direction.

  Moreover, when the heat radiating plate 32 is formed of a magnetic material, the lighting fixture 200 may be configured such that the heat radiating plate 32 is magnetized by magnetizing the heat radiating plate 32. Furthermore, the luminaire 200 may be configured to allow a weak current to flow through the heat radiating plate 32. It is considered that the lighting fixture 200 is likely to have a tendency for birds to avoid the heat radiating plate 32 due to a configuration in which the heat radiating plate 32 of the light source unit 1 has magnetism or a configuration in which a weak current flows. The lighting fixture 200 can be configured such that, for example, a voltage of 6500 V to 9000 V is applied to the heat sink 32 and a weak current of 0.13 A to 0.16 A can flow to the heat sink 32. The lighting fixture 200 should just be comprised so that electrical insulation may be maintained between the heat sink 32 and the base part 30 so that the polarity of the adjacent heat sink 32 may differ. The lighting fixture 200 may be configured to allow a weak current to flow through the heat radiating plate 32 in a pulse manner at a predetermined interval.

  The lens block 4 is configured to cover the LED module 2. As shown in FIGS. 16 to 18, the lens block 4 includes a main body 40 and a lens 41. The main body 40 has a bottom plate 400 and a peripheral wall 401. The bottom plate 400 has a rectangular flat plate outer shape. The peripheral wall 401 is provided on the outer peripheral edge of the bottom plate 400 so as to protrude along the thickness direction of the bottom plate 400. The bottom plate 400 is provided with a plurality of lenses 41 in a two-dimensional array so as to correspond one-to-one with the LEDs 20 of the LED module 2. The main body 40 includes a hook piece 402 protruding from the peripheral wall 401 in a direction orthogonal to the thickness direction of the bottom plate 400. The hook piece 402 is formed in a concave shape in plan view. Two hook pieces 402 are provided along one side of the rectangular bottom plate 400 in plan view. The hook pieces 402 are provided on two opposite sides of the bottom plate 400. The peripheral wall 401 is provided with three fixing pieces 403 in plan view. The fixed piece 403 is configured to protrude from the end edge of the peripheral wall 401. The fixed piece 403 has an L-shaped outer shape in a side view. The fixed piece 403 has a rectangular shape in plan view. The fixed piece 403 includes a C-shaped opening 403cc at the center. The fixed piece 403 includes a first fixed piece 403a provided between the pair of hook pieces 402 and a second fixed side 403b provided on one side of the bottom plate 400 that is orthogonal to the side on which the hook pieces 402 are provided. It has a configuration with. The lens block 4 is integrally formed with a main body 40, a lens 41, a hook piece 402, and a fixed piece 403. As the material of the lens block 4, for example, a synthetic resin material having translucency such as an acrylic resin can be used.

  As shown in FIG. 6, the attachment member 5 is configured to cover the LED module 2 and be fixed to the heat radiating member 3. The attachment member 5 is interposed between the LED module 2 and the lens block 4. The attachment member 5 is configured so that the lens block 4 can be attached. As shown in FIGS. 19 to 21, the attachment member 5 includes a base 50, a peripheral wall portion 51, a flange 52, and a support portion 53. The base 50 is formed in a rectangular flat plate shape. The base 50 is formed such that a plurality of concave portions 500 are arranged in a two-dimensional array in plan view. The recess 500 is formed in a rectangular shape in plan view. The recess 500 includes a first recess 500a, a second recess 500b, and a third recess 500c. A plurality of first recesses 500a are provided so as to correspond to the LEDs 20 on a one-to-one basis. A circular window hole 501 is opened in the center of the first recess 500a. The first recess 500 a is configured so that light emitted from the LED 20 can enter the lens 41 through the window hole 501. The base 50 is formed with a second recess 500b at the center in plan view. The second recess 500b is formed in a rectangular shape. The second recess 500b has a first screw insertion hole 502 having a smaller diameter than the window hole 501 of the first recess 500a. The base 50 includes third recesses 500c at opposite edges in plan view. Two third recesses 500c are provided along one edge. The third recess 500c is formed in a rectangular shape. The third recess 500c is smaller than the first recess 500a and the second recess 500b. The third recess 500c has a rectangular opening hole 5000.

  As shown in FIG. 20, the base 50 has a plurality of pressing portions 503 arranged in a two-dimensional array in plan view. The pressing portion 503 is formed so as to protrude from the surface of the base 50 into a truncated pyramid shape. The base 50 is formed so that the concave portion 500 and the pressing portion 503 overlap in the thickness direction. The pressing part 503 has a first pressing part 503a and a second pressing part 503b. The first pressing portion 503a is provided so as to correspond to the first recess 500a. An opening communicating with the window hole 501 of the first recess 500a is formed at the center of the first pressing portion 503a. The second pressing portion 503b is provided so as to correspond to the second recess 500b. The first screw insertion hole 502 of the second recess 500b passes through the center of the second pressing portion 503b.

  The peripheral wall 51 is formed in a rectangular frame shape along the outer periphery of the base 50 in plan view. The peripheral wall portion 51 protrudes in the thickness direction of the base 50. In the base 50, the protruding amount of the peripheral wall portion 51 protruding from the surface where the pressing portion 503 is provided is larger than the protruding amount of the peripheral wall portion 51 protruding from the surface where the concave portion 500 is provided. Below, the peripheral wall part 51 which protrudes along the thickness direction of the base 50 from the surface in which the recessed part 500 was provided is called 1st peripheral wall part 51a, and it follows the thickness direction of the base 50 from the surface in which the press part 503 was provided. The protruding peripheral wall 51 is also referred to as a second peripheral wall 51b. A plurality of columnar protrusions 510 are provided on the flat surface of the first peripheral wall 51a. The first peripheral wall portion 51a includes eight projecting portions 510. The first peripheral wall portion 51 a has a recess 511 formed in a portion adjacent to the opening hole 5000 of the base 50. The flange 52 is provided so as to protrude outward from the peripheral surface of the peripheral wall portion 51 over the entire periphery. The flange 52 is provided with screw insertion grooves 520 at four corners in plan view. The flange 52 is also provided with two screw insertion grooves 520 at portions corresponding to the four sides of the rectangular base 50. The support part 53 has a rectangular plate-like outer shape. The support portion 53 is formed so as to protrude from the surface side of the base 50 where the pressing portion 503 is provided. Two support portions 53 are provided on each of opposite sides of the rectangular frame-shaped flange 52. The support portion 53 includes a claw 530 at a plate-like tip. The claw 530 has a triangular prism-like outer shape. The claw 530 of the support portion 53 protrudes in a direction approaching the peripheral wall portion 51. In the attachment member 5, the base 50, the peripheral wall portion 51, the flange 52, and the support portion 53 are integrally formed. As the material of the attachment member 5, for example, a synthetic resin material such as PBT (polybutylene terephthalate) resin can be used.

  The heat conductive sheet 6 is provided to efficiently transfer heat generated by the LEDs 20 from the mounting substrate 21 to the heat dissipation member 3. The heat conductive sheet 6 is formed in a rectangular sheet-like outer shape. As shown in FIG. 6, a circular hole 60 is provided at the center of the heat conductive sheet 6 so as to correspond to the first hole portion 210 of the mounting substrate 21. The heat conductive sheet 6 can be made of an elastomer material that is excellent in electrical insulation and heat conductivity and has elasticity. As the heat conductive sheet 6, for example, a silicone gel sheet can be used. The silicone gel sheet is configured using a silicone resin having a gel shape and a low crosslinking density. The heat conductive sheet 6 may contain a heat conductive filler in the silicone resin. The heat conductive sheet 6 may use not only a silicone gel sheet but also a sheet-like acrylic resin.

  As shown in FIG. 6, the cover block 7 includes a cover 70, a pressing plate 71, and a seal member 72. The cover 70 has a cover main body 700 and an outer casing 701. The cover body 700 has a bottomed rectangular tube-like outer shape. The outer casing 701 protrudes outward from the edge of the cover body 700. The outer casing 701 has a rectangular frame-like outer shape in plan view. Circular fitting holes 702 are provided at the four corners of the outer casing 701. Three circular second screw insertion holes 703 are provided on the four sides of the outer casing 701 at predetermined intervals. The cover 70 can integrally form the cover main body 700 and the outer casing 701. As the material of the cover 70, for example, a synthetic resin material having translucency such as polycarbonate resin can be used.

  The holding plate 71 has a main piece 710 and side pieces 711. The main piece 710 has a belt-like outer shape. The main piece 710 is provided with third screw insertion holes 712 at both ends and the center in the longitudinal direction. The side piece 711 extends from one end edge along the longitudinal direction of the main piece 710 in a direction orthogonal to the main piece 710. The presser plate 71 integrally forms a main piece 710 and a side piece 711. The holding plate 71 can be formed by punching or bending a metal plate. As a material of the pressing plate 71, for example, a metal material such as stainless steel can be used.

  The seal member 72 is formed in a rectangular frame-like outer shape. The seal member 72 is formed in the same size as the outer flange 701 in the cover 70. The seal member 72 has protrusions 720 at four corners. The protrusion 720 is formed in the same shape as the outer shape of the bolt. The seal member 72 includes a fourth screw insertion hole 721. A plurality of fourth screw insertion holes 721 are provided along each side of the seal member 72. The seal member 72 can be formed of, for example, a silicone resin.

  Next, the procedure for assembling the light source unit 1 will be described.

  In the assembly process of the light source unit 1, the heat conductive sheet 6 is laid on the first surface 30 aa of the base portion 30 in the heat radiating member 3. In the assembly process, the LED module 2 and the attachment member 5 are placed in order on the heat conductive sheet 6. As for the attachment member 5, the LED module 2 is engage | inserted inside the 2nd surrounding wall part 51b. In the assembly process, the attachment member 5 is fixed to the base portion 30 by screwing the first screw 54 inserted into the screw insertion groove 520 in the attachment member 5 into the first screw hole 300 of the base portion 30. The LED module 2 is attached to the heat dissipation member 3 via the heat conductive sheet 6 by the attachment member 5 fixed to the base portion 30. The LED 20 of the LED module 2 is disposed so as to correspond to the position of the window hole 501 of the attachment member 5. Subsequently, in the assembly process, the plug connector is connected to the receptacle connector 22 of the LED module 2 via the opening hole 5000 of the third recess 500 c in the mounting member 5. In the assembly process, the power supply line 23 to which the plug connector is connected is inserted through the first insertion hole 301 of the base portion 30 through the cable gland 33.

  Next, in the assembly process, the lens block 4 covers the attachment member 5. In the assembly process, the claw 530 of the support portion 53 of the attachment member 5 is hooked on the hook piece 402 of the lens block 4. In the assembly process, the peripheral wall 401 of the lens block 4 is placed on the peripheral wall portion 51 of the mounting member 5. In the light source unit 1, the power supply line 23 is drawn out of the lens block 4 through a recess 511 provided in the first peripheral wall portion 51 a of the mounting member 5. The lens block 4 is supported by the support portion 53 of the attachment member 5. In the lens block 4, the fixed piece 403 is screwed to the base portion 30. In the assembly process, the screw tightening torque is set to such an extent that the lens block 4 is not distorted as the fixing piece 403 is screwed.

  Finally, in the assembly process, the cover block 7 is attached to the base portion 30. In the cover block 7, the protrusion 720 of the seal member 72 is fitted into the fitting hole 702 of the cover 70, and the seal member 72 is attached to the cover 70. In the assembly process, the cover 70 to which the seal member 72 is attached is put on the lens block 4. In the assembly process, the pressing plate 71 is attached to the outer flange 701 of the cover 70, the third screw insertion hole 712 of the holding plate 71, the second screw insertion hole 703 of the cover 70, and the fourth screw insertion hole 721 of the seal member 72. Are placed so that they match. In the cover block 7, the second screw 73 is inserted through the third screw insertion hole 712 of the holding plate 71, the second screw insertion hole 703 of the cover 70, and the fourth screw insertion hole 721 of the seal member 72. The second screw 73 is screwed into the first screw hole 300 of the base portion 30. In the cover block 7 and the heat radiating member 3, a pressing plate 71, a cover 70, and a seal member 72 are fixed to the base portion 30 by a second screw 73. The light source unit 1 can be assembled by the assembly process described above. The light source unit 1 is not limited to the case where the heat dissipation member 3 and the LED module 2 are configured to contact each other indirectly through another member such as the heat conductive sheet 6. You may comprise so that may contact | connect directly.

  Next, the lighting fixture 200 of this embodiment is demonstrated with reference to FIG. 1 thru | or FIG.

  The lighting fixture 200 includes the light source unit 1 and the holding unit 9. The lighting fixture 200 includes four light source units 1. In the lighting fixture 200 of this embodiment, the four light source units 1 are integrated by the connecting member 8. The connecting member 8 includes a first connecting member 10, a second connecting member 11, and a third connecting member 12. The connecting member 8 preferably has an auxiliary connecting member 8a. The holding unit 9 includes an arm 16 that holds the plurality of light source units 1 integrated by the connecting member 8. The lighting fixture 200 preferably includes a wiring box 15 and a wire 17. In the lighting fixture 200, since the plurality of light source units 1 are connected by the first connecting member 10, the second connecting member 11, and the third connecting member 12, the plurality of light source units 1 are integrated with a relatively simple configuration. Can be achieved.

  The first connecting member 10 includes a strip-shaped main portion 100 and an auxiliary piece 101 that protrudes in the thickness direction of the main portion 100 along the longitudinal direction of the main portion 100. The main part 100 and the auxiliary piece 101 can be integrally formed of, for example, a metal plate. The main part 100 and the auxiliary piece 101 can be formed by bending a metal plate. As a material of the first connecting member 10, for example, a metal material such as stainless steel can be used. However, the material is not limited to the metal material, and may be formed of a resin material. The first connecting member 10 is provided with a first projecting piece 102 at an end portion in the longitudinal direction of the main portion 100. The first connecting member 10 is provided with a second projecting piece 103 at the center in the longitudinal direction of the main portion 100. The tip of the second protrusion 103 is bent outward. The first connecting member 10 is attached to the two light source units 1 by combining the first protruding piece 102 and the second protruding piece 103 with the second connecting portion 310 provided on the edge 31 of the heat radiating member 3. . In the lighting fixture 200, the third screw 104 inserted through the first projecting piece 102 and the second projecting piece 103 is screwed into the second coupling portion 310 of the light source unit 1.

  The second connecting member 11 includes a central part 110 and end parts 111 provided on both sides of the central part 110. The second connecting member 11 has a belt-like outer shape with a central portion 110 and an end portion 111. The second connecting member 11 is configured such that the central portion 110 protrudes in the thickness direction with respect to the end portion 111, and has a step between the end portion 111 and the central portion 110. In the lighting fixture 200, a fourth screw 112 inserted through the central portion 110 and the end portion 111 of the second connecting member 11 is screwed into the third coupling portion 311 of the light source unit 1. As the material of the second connecting member 11, for example, stainless steel can be used. The second connecting member 11 is coupled to the third coupling portion 311 provided at the edge 31 of the heat dissipation member 3. The second connecting member 11 is attached to the two light source units 1 by being coupled to the third coupling portion 311 of the heat radiating member 3.

  The third connecting member 12 has a belt-like outer shape. As for the 3rd connection member 12, the both ends of a transversal direction are bent in the thickness direction along the longitudinal direction. The strength of the third connecting member 12 is increased by bending both ends in the lateral direction in the thickness direction. As the material of the third connecting member 12, for example, stainless steel can be used. As shown in FIGS. 4 and 8, the third connecting member 12 is configured such that the fifth screw 120 is coupled to the first coupling portion 312 provided at the edge portion 31 of the heat radiating member 3, so that the four light source units 1. Attached to.

  The auxiliary connecting member 8 a includes an arm mounting member 13 and a reinforcing member 14. A pair of arm attachment members 13 are provided. A pair of reinforcing members 14 are provided. As shown in FIG. 5, the arm attachment member 13 has a fixed portion 130, an attachment portion 131, and a bearing portion 132. The arm attachment member 13 includes a fixed portion 130, an attachment portion 131, and a bearing portion 132 that are integrally formed. In the arm attachment member 13, the fixed portion 130, the attachment portion 131, and the bearing portion 132 are formed by, for example, aluminum die casting.

  The fixing portion 130 is configured to be fixed to the edge portion 31 in the light source unit 1. The fixing unit 130 has a bottom wall 1300, a first side wall 1301, and a second side wall 1302. The first side wall 1301 is formed in a rectangular flat plate shape. The first side wall 1301 is formed so as to protrude in the thickness direction of the bottom wall 1300 from one end edge in the short direction of the bottom wall 1300 along the longitudinal direction of the bottom wall 1300. The second side wall 1302 is formed in a rectangular flat plate-like outer shape. The second side wall 1302 is formed so as to protrude in the same direction as the first side wall 1301 from the other end edge in the short direction of the bottom wall 1300 along the longitudinal direction of the bottom wall 1300. The fixed part 130 is formed in a square-hull-like outer shape by the bottom wall 1300, the first side wall 1301, and the second side wall 1302. The lighting fixture 200 can increase the mechanical strength by fitting and attaching the second side wall 1302 of the arm attachment member 13 to the groove 34 of the heat dissipation member 3.

  A pair of attachment portions 131 are provided on the fixed portion 130. The attachment part 131 has a frustoconical outer shape. The attachment portion 131 is provided so as to protrude from the bottom wall 1300 of the fixed portion 130. A female screw is formed at the tip of the attachment portion 131. The mounting portion 131 has a scale plate 133 in one arm mounting member 13 of the pair of mounting portions 131. As shown in FIG. 2, the scale plate 133 is formed in a fan-shaped flat plate. The scale plate 133 is engraved with a scale so that the angle of the light source unit 1 with respect to the installation surface 9aa can be indicated. The scale plate 133 is connected to the tip end portion of the bearing portion 132 in the one arm mounting member 13.

  The bearing portion 132 has a cylindrical outer shape. The bearing portion 132 is disposed between the pair of attachment portions 131. The bearing portion 132 is configured to be connected to the attachment portion 131 and the bottom wall 1300 of the fixed portion 130.

  The reinforcing member 14 has a belt-like outer shape. The reinforcing member 14 is bent in the thickness direction at both ends in the lateral direction along the longitudinal direction. The reinforcing member 14 has high mechanical strength because both ends in the short direction are bent in the thickness direction. The reinforcing member 14 is configured to be attached to the attachment portion 131 by the first bolt 140. As a material of the reinforcing member 14, for example, a metal material such as stainless steel can be used.

  The wiring box 15 is formed in a rectangular box-like outer shape. The wiring box 15 houses a relay terminal block. The wiring box 15 is configured so that a power cable drawn from the outside and the power supply line 23 of the light source unit 1 can be connected by a terminal block. The power cable is connected to a power supply device installed outside the wiring box 15. The lighting fixture 200 is supplied with power from the power supply device to the light source unit 1 via the terminal block of the wiring box 15. The luminaire 200 is not limited to a structure in which the power supply device is installed outside the wiring box 15, and may be configured to store the power supply device inside the wiring box 15. As a material of the wiring box 15, for example, a metal material such as stainless steel can be used.

  The holding unit 9 is configured by an arm 16 including a fixed plate 160, a rising piece 161, and a support piece 162. The holding unit 9 may be configured to hold the light source unit 1 at a predetermined angle with respect to the installation surface 9aa, and is not limited to the structure configured by the arm 16. The fixed plate 160 has a flat outer shape. The fixing plate 160 is used for fixing to the installation surface 9aa. The fixing plate 160 has a circular fixing hole passing through the center. As shown in FIG. 1, the fixing plate 160 is provided with a semicircular arc-shaped hole 1600 centered on the fixing hole. The fixing plate 160 is fixed to a projector stand or the like where the fixing plate 160 serves as the installation surface 9aa by a second bolt inserted through the fixing hole and a third bolt inserted through the elongated hole 1600. The rising piece 161 is provided so as to rise from the end of the fixed plate 160. A pair of rising pieces 161 are provided so as to face each other through the fixed plate 160. The support piece 162 is provided so as to extend from the tip of the rising piece 161 rising from the fixed plate 160.

  The arm 16 integrally forms a fixed plate 160, a rising piece 161, and a support piece 162. As a material of the arm 16, for example, a metal material such as stainless steel can be used. The arm 16 can be formed by punching or bending a metal plate. The arm 16 loosens the third bolt inserted through the long hole 1600 of the fixing plate 160 so that the direction of the light source unit 1 held by the arm 16 can be appropriately changed along the horizontal direction. It is configured.

  In the lighting fixture 200, the fourth bolt 163 inserted through the support piece 162 is screwed into the bearing portion 132 of the arm attachment member 13. In the lighting device 200, the fourth bolt 163 is fixed to the bearing portion 132, whereby the four light source units 1 connected by the connecting member 8 can be rotatably held by the holding portion 9. The lighting fixture 200 can indicate the angle of the light source unit 1 with respect to the installation surface 9aa around the fourth bolt 163 by the scale plate 133 provided on the arm attachment member 13. The lighting fixture 200 is configured such that the light source unit 1 can be changed to a predetermined angle with respect to the installation surface 9aa by rotating the lever 37.

  Below, the assembly process in the lighting fixture 200 of this embodiment is demonstrated.

  In the assembly process of the lighting fixture 200, two light source units 1 of the four light source units 1 are connected by the first connecting member 10. Subsequently, in the assembly process of the lighting fixture 200, the fixing portion 130 of the arm attachment member 13 and the edge portion 31 of the heat radiating member 3 in the light source unit 1 are fitted together. In the assembly process of the lighting fixture 200, the second connecting member 11 overlaps the fixed portion 130 and the edge portion 31 so that the center portion 110 of the second connecting member 11 and the fixed portion 130 of the arm attachment member 13 are aligned. Are arranged as follows. In the lighting fixture 200, the end portion 111 of the second connecting member 11 and the third coupling portion 311 at the edge portion 31 of the heat dissipation member 3 are screwed together. In the luminaire 200, the first side wall 1301 of the fixing portion 130 and the central portion 110 of the second connecting member 11 are screwed to the third coupling portion 311 of the edge portion 31. In the lighting fixture 200, a set of two light source units 1 connected by the first connecting member 10 is connected by the second connecting member 11. The lighting apparatus 200 is integrated by connecting the four light source units 1 with the first connecting member 10 and the second connecting member 11. As shown in FIG. 4, in the lighting fixture 200, the first coupling portion 312 of the four light source units 1 coupled to each other and the third coupling member 12 are coupled. In the lighting fixture 200, the mechanical strength for connecting the light source units 1 can be increased by connecting the four light source units 1 not only with the first connecting member 10 and the second connecting member 11 but also with the third connecting member 12. it can.

  Next, in the assembly process of the lighting fixture 200, the reinforcing member 14 and the attachment portion 131 in the arm attachment member 13 are fixed by the first bolt 140. Subsequently, in the assembly process of the lighting apparatus 200, the wiring box 15 is attached to the reinforcing member 14. In the lighting fixture 200, after the wiring box 15 is attached to the reinforcing member 14, the lighting fixture 200 may be assembled by attaching the reinforcing member 14 to the attaching portion 131 of the arm attaching member 13. In the assembly process of the luminaire 200, after the wiring box 15 is attached to the reinforcing member 14, the connection work of the power cable and the feeder line 23 is performed. Finally, in the assembly process of the lighting device 200, the fourth bolt 163 inserted through the support piece 162 is screwed into the fifth screw hole provided in the bearing portion 132 of the arm mounting member 13, so that the arm 16 and the arm mounting are mounted. The member 13 is attached.

  When the lighting fixture 200 of the present embodiment is installed on the installation surface 9aa of the projector base, both ends of the metal wire 17 are screwed to the central portion 110 of the second connecting member 11 as shown in FIGS. It is preferable to stop. The wire 17 is preferably supported by a wire receiver 18 fixed to the installation surface 9aa. In the lighting fixture 200, even when the arm 16 is detached from the installation surface 9aa such as the projector stand, the wire 17 supports the arm 16 so that the lighting fixture 200 is prevented from falling.

DESCRIPTION OF SYMBOLS 1 Light source unit 3 Heat radiating member 9 Holding part 9aa Installation surface 20 LED (solid light emitting element)
21 mounting board 30 base part 30aa 1st surface 30ab 2nd surface 32 heat sink 32a front-end | tip part 35 protrusion piece 200 lighting fixture

Claims (5)

A light source unit having a solid light emitting element, a mounting board on which the solid light emitting element is mounted, a heat radiating member that mounts the mounting board and dissipates heat generated by the solid light emitting element; A holding portion that holds at an angle of
The heat dissipating member has a base portion on which the mounting substrate is mounted, and a heat dissipating plate protruding from a second surface opposite to the first surface on which the mounting substrate of the base portion is mounted,
The heat radiating plate has a plate-like outer shape, a plurality of parallel lines are arranged on the base portion, and the tip of the heat radiating plate has a thickness dimension that decreases toward the tip. Characteristic lighting equipment.   The lighting device according to claim 1, wherein the heat sink has a rounded shape at a rectangular corner at the tip in the thickness direction.   The lighting device according to claim 1, wherein the heat sink has a protruding direction with respect to the base portion inclined with respect to the second surface.   The lighting device according to any one of claims 1 to 3, wherein the heat radiating plate includes a protruding piece protruding along a direction parallel to the second surface at the tip portion. .   The length of the said heat sink from the said base part to the said front-end | tip differs in the said adjacent heat sink among the several said heat sinks. The lighting fixture as described in.

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