JP7471385B2 - Light source unit - Google Patents

Description

The present invention relates to a light source unit equipped with a light distribution control member that controls the distribution of light emitted from a light-emitting element.

Conventionally, light source units are known that control the distribution of light emitted from light-emitting elements such as LEDs using a light distribution control member such as a lens. Patent Document 1 discloses a light source unit that includes a board on which LEDs are mounted, a heat dissipation member to which the board is attached, and a light distribution control member that controls the light distribution of the LEDs. In the light source unit of Patent Document 1, multiple LEDs are mounted on the board, and multiple lenses of the light distribution control member are arranged to face each of the multiple LEDs.

JP 2013-243033 A

However, in the light source unit disclosed in Patent Document 1, the multiple lenses of the light distribution control member must be positioned to face each of the multiple LEDs. This makes the manufacturing process complicated.

The present invention has been made to solve the above problems, and provides a light source unit that makes it easy to position the light distribution control member and the light emitting element.

The light source unit of the present invention comprises a light-emitting element, a substrate on which the light-emitting element is mounted and on which a substrate engagement hole is formed, a light distribution control member having a claw portion protruding toward the substrate and attached to the substrate so as to cover the light-emitting element by engaging the claw portion with the substrate engagement hole, and controlling the distribution of light emitted from the light-emitting element, a base portion having a recess on one side to which the substrate is attached and in which the claw portion of the light distribution control member is accommodated, and a fin portion provided approximately perpendicularly on the back surface opposite the one surface of the base portion, the recess portion being formed on a pedestal at the portion of the base portion that comes into contact with the substrate, and the multiple recesses being connected in an approximately donut shape .

According to the present invention, the light distribution control member is attached to the board on which the light-emitting element is mounted by engaging the claw portion of the light distribution control member with the board engagement hole of the board. Therefore, the light distribution control member and the board can be overlapped so that the claw portion and the board engagement hole face each other. This makes it easy to position the light distribution control member and the light-emitting element.

1 is an assembled perspective view showing a lighting fixture 1 according to a first embodiment of the present invention. 1 is an exploded perspective view showing a lighting fixture 1 according to a first embodiment of the present invention. 1 is a side view showing a lighting device 1 according to a first embodiment of the present invention. FIG. 2 is another side view showing the lighting fixture 1 according to the first embodiment of the present invention. 2 is an assembled perspective view of the light source unit 210 according to the first embodiment of the present invention, as viewed from below. FIG. 2 is an assembled perspective view of a light source unit 210 according to the first embodiment of the present invention, as viewed from above. FIG. 2 is an exploded perspective view of a light source unit 210 according to the first embodiment of the present invention, as viewed from below. FIG. 2 is an exploded perspective view of a light source unit 210 according to the first embodiment of the present invention as viewed from above. FIG. 2 is an exploded perspective view of a heat sink 220 according to the first embodiment of the present invention, as viewed from above. FIG. FIG. 2 is a perspective view showing a base portion 221 according to the first embodiment of the present invention. FIG. 2 is a perspective view showing a fin 223a according to the first embodiment of the present invention. 2 is a top view of the heat sink 220 according to the first embodiment of the present invention when a canopy portion 222 is removed. FIG. 2 is a side view showing a light source fixture 215 according to the first embodiment of the present invention. FIG. 2 is a perspective view of a heat sink 220 and a light source unit 210 according to the first embodiment of the present invention during assembly. FIG. 2 is a perspective view of a heat sink 220 and a light source unit 210 according to the first embodiment of the present invention during assembly. FIG. 2 is a perspective view of a heat sink 220 and a light source unit 210 according to the first embodiment of the present invention during assembly. FIG. FIG. 2 is a perspective view showing a cover 240 according to the first embodiment of the present invention. 2 is a side cross-sectional view showing a fixing portion 120 according to the first embodiment of the present invention. FIG. 1 is an assembled perspective view showing a functional unit 1000 according to a first embodiment of the present invention. 1 is an exploded perspective view of a functional unit 1000 according to a first embodiment of the present invention, as viewed from the front side. 1 is an exploded perspective view of a functional unit 1000 according to a first embodiment of the present invention, as viewed from the rear side. 1 is a perspective view showing a case where a functional unit 1000 according to a first embodiment of the present invention is attached. FIG. 1 is a perspective view showing a case where a functional unit 1000 according to a first embodiment of the present invention is attached. FIG. 1 is a perspective view showing a case where a functional unit 1000 according to a first embodiment of the present invention is attached. FIG. 1 is a side cross-sectional view of a functional unit 1000 according to a first embodiment of the present invention. FIG. 13 is an assembled perspective view showing a functional unit 1300 according to a second embodiment of the present invention. FIG. 13 is an exploded perspective view showing a functional unit 1300 according to a second embodiment of the present invention. 13 is an assembled perspective view showing a functional section 1500 according to embodiment 3 of the present invention. FIG. FIG. 15 is an exploded perspective view showing a functional unit 1500 according to a third embodiment of the present invention. FIG. 11 is a side view of a lighting device 1 according to a third embodiment of the present invention. FIG. 11 is a perspective view showing a lighting fixture 1a according to a fourth embodiment of the present invention. FIG. 16 is a perspective view showing an arm 1600 according to a fifth embodiment of the present invention. FIG. 13 is an assembled perspective view showing a heat sink 220 according to a sixth embodiment of the present invention. FIG. 13 is an exploded perspective view of a heat sink 220 according to a sixth embodiment of the present invention, as viewed from below. FIG. 13 is a perspective view showing a fin 223a according to a sixth embodiment of the present invention. FIG. 13 is an assembled perspective view showing a lighting fixture 1b according to a seventh embodiment of the present invention. FIG. 13 is an exploded perspective view showing a lighting device 1b according to a seventh embodiment of the present invention.

Embodiment 1.
Hereinafter, embodiments of a light source unit and a lighting fixture according to the present invention will be described with reference to the drawings. Fig. 1 is an assembled perspective view showing a lighting fixture 1 according to the first embodiment of the present invention, and Fig. 2 is an exploded perspective view showing the lighting fixture 1 according to the first embodiment of the present invention. Fig. 3 is a side view showing the lighting fixture 1 according to the first embodiment of the present invention, and Fig. 4 is another side view showing the lighting fixture 1 according to the first embodiment of the present invention. As shown in Figs. 1 to 4, the lighting fixture 1 is attached to a ceiling or the like, and includes a support part 100 attached to a mounting part (not shown) of the ceiling or the like, a light source unit 200 held by the support part 100, and a functional unit 1000 having, for example, a communication function.

(Support portion 100)
The support part 100 has an arm 110, a fixing part 120, a connecting part 130, and a fall prevention part 140. The arm 110 is, for example, a member formed into a U-shape by bending a metal plate, and is attached to the mounting part by a fastener such as a bolt. The fixing part 120 is, for example, a member formed by bending both ends of a flat metal plate, and holds the light source unit 200. The connecting part 130 connects the arm 110 and the fixing part 120, and is, for example, made of two bolts and two nuts. The fixing part 120 is formed of a rigid metal, and is attached to the arm 110 so as to be able to swing freely by the connecting part 130.

The fall prevention part 140 has an attachment part 142 that is attached to the attachment part, and a wire 141 that connects the attachment part 142 and the fixed part 120. The fall prevention part 140 prevents the light source unit 200 from falling even if the light source unit 200 comes off the arm 110.

(Light source unit 200)
The light source unit 200 has a light source section 210 that irradiates light, and a heat sink 220 that dissipates heat from the light source section 210. The light source unit 200 also has a power supply unit 230 that supplies power to the light source section 210 to turn it on, a cover 240 that is attached to the heat sink 220 so as to cover the light source section 210, and a light source fixture 215.

(Light source unit 210)
Fig. 5 is an assembled perspective view of the light source unit 210 according to the first embodiment of the present invention when viewed from below, and Fig. 6 is an assembled perspective view of the light source unit 210 according to the first embodiment of the present invention when viewed from above. Fig. 7 is an exploded perspective view of the light source unit 210 according to the first embodiment of the present invention when viewed from below, and Fig. 8 is an exploded perspective view of the light source unit 210 according to the first embodiment of the present invention when viewed from above. As shown in Figs. 5 to 8, the light source unit 210 has a light emitting unit 213 that irradiates light and a light distribution control member 214 that controls the light distribution of the light irradiated from the light emitting unit 213.

The light-emitting section 213 has a plurality of light-emitting elements 211 and a substrate 212 on which the plurality of light-emitting elements 211 are arranged radially. The substrate 212 is substantially rectangular in shape, with the four corners rounded. The substrate 212 is formed with a substrate fixing hole 212a, a notch 212b, and a substrate engagement hole 212c. The substrate fixing hole 212a is formed in the center of the substrate 212, and the notch 212b is formed in one location on the edge of the substrate 212. The substrate engagement holes 212c are formed in six locations on the edge of the substrate 212.

The light distribution control member 214 has a plurality of lenses 214a, a tube portion 214b, and a plurality of claw portions 214c. The lenses 214a are arranged to face each of the plurality of light-emitting elements 211, and control the traveling direction of the light irradiated from the light-emitting elements 211. The tube portion 214b is a cylindrical member provided in the center of the light distribution control member 214 and communicates with the substrate fixing hole 212a. The claw portion 214c is a member that protrudes toward the substrate 212, and is attached to the substrate 212 so as to cover the light-emitting element 211 by engaging with the substrate engagement hole 212c. In this way, the light source unit 210 is attached to the heat sink 220 with the light distribution control member 214 attached to the light-emitting unit 213 in advance. Here, when the light source unit 210 is assembled, the light distribution control member 214 and the substrate 212 may be overlapped so that the claw portion 214c and the substrate engagement hole 212c face each other. This makes it easy to position the light distribution control member 214 and the light emitting element 211. This improves the ease of assembly of the light source unit 210. In addition, since the light distribution control member 214 is not fixed to the heat sink 220 by screws or the like, it is possible to prevent the light distribution control member 214 from shifting in position when the screws are tightened.

(Heat sink 220)
9 is an exploded perspective view of the heat sink 220 according to the first embodiment of the present invention, viewed from above. As shown in FIG. 9, the heat sink 220 has a rectangular columnar shape, and includes a rectangular plate-shaped base portion 221, a fin portion 223 having a plurality of fins 223a, and a rectangular plate-shaped eaves portion 222 covering the fin portion 223. The base portion 221, the fin portion 223, and the eaves portion 222 are formed by processing, for example, an aluminum plate, and the heat sink 220 is manufactured by combining them. The heat sink 220 is formed by sheet metal processing of an aluminum plate, which makes it possible to reduce the weight compared to injection molding, and since a mold for molding is not required, the manufacturing cost can be reduced. Note that the aluminum plate has a higher aluminum purity than the aluminum material used in injection molding, and even if the plate thickness is thin, it is possible to ensure heat dissipation equal to or greater than that of the aluminum material used in injection molding.

10 is a perspective view showing the base portion 221 according to the first embodiment of the present invention. As shown in FIG. 10, the base portion 221 has a first base surface 21a to which the light source portion 210 is attached, and a second base surface 21b on the back side of the first base surface 21a. One surface of the heat sink 220 of the present invention corresponds to the first base surface 21a of the base portion 221. The fin portion 223 is placed approximately perpendicularly on the second base surface 21b. Note that the fin portion 223 does not have to be completely perpendicular to the second base surface 21b, as long as it is at an angle that intersects with the second base surface 21b. The first base surface 21a of the base portion 221 is provided with a cylindrical bush 250 used when drawing the electric wire 260 to the light source portion 210 side. The bush 250 is inserted into the notch 212b formed in the substrate 212, making it easy to position the base portion 221 and the substrate 212.

The base portion 221 has a recess 221b, in which a light source fixing hole 221c and a cover fixing hole 221d are formed. The recess 221b is recessed from the surface of the base portion 221, and six recesses 221b are provided on the edge of the base portion 221. The recess 221b accommodates the claw portion 214c of the light distribution control member 214. The light source fixing hole 221c is formed in the center of the base portion 221, and communicates with the tube portion 214b and the board fixing hole 212a of the light distribution control member 214. The cover fixing hole 221d is used when the cover 240 and the base portion 221 are attached, and eight cover fixing holes 221d are formed on the edge of the base portion 221. Note that the recess 221b may have a structure that accommodates the claw portion 214c of the light source portion 210 so as not to hinder contact between the base portion 221 and the board 212, and the multiple recesses 221b may be connected in a substantially donut-like shape rather than being separate. The recess 221b may also be formed on the base 221 at the portion that comes into contact with the substrate 212.

11 is a perspective view showing the fin 223a according to the first embodiment of the present invention. The fin portion 223 has a plurality of fins 223a arranged radially, a base connection portion 223b connected to the base portion 221, and an eave connection portion 223c connected to the eave portion 222. The heat sink 220 can ventilate from the entire circumference of the lighting fixture 1 because the plurality of fins 223a are arranged radially, thereby improving heat dissipation. As shown in FIG. 11, the fins 223a are arranged in pairs, and the lower ends of the fins 223a are connected to each other by the base connection portion 223b. The upper end of one of the two fins 223a is provided with an eave connection portion 223c. The base connection portion 223b is fixed to the base portion 221, and the fixing means may be welding such as laser welding, or may be a fixing member such as a rivet. The eaves connection part 223c is fixed to the eaves part 222, and the fixing means may be welding such as laser welding, or may use a fixing member such as a rivet.

Figure 12 is a top view of the heat sink 220 according to the first embodiment of the present invention with the eaves portion 222 removed. As shown in Figure 12, the connection portion 130 is disposed between the fins 223a. Therefore, the fins 223a do not interfere with the connection portion 130. Therefore, the fins 223a do not need to be retracted inward so as not to interfere with the connection portion 130, and can extend to the edge of the base portion 221. Therefore, the lighting device 1 can easily provide natural convection to the fins 223a. This allows the heat sink 220 to enhance its heat dissipation effect.

9, the eaves portion 222 has the same shape as the base portion 221, and has a first eaves surface 22a that faces and contacts the fin portion 223, and a second eaves surface 22b on the back side of the first eaves surface 22a. The power supply unit 230 is placed on the second eaves surface 22b. Here, the fixing portion 120 of the holding portion connects the first base surface 21a of the base portion 221 and the first eaves surface 22a of the eaves portion 222 (see FIG. 1). The eaves portion 222 has an eaves through hole 222b used to attach the functional unit 1000. Two eaves through holes 222b are provided on the side side perpendicular to the side of the eaves portion 222 to which the fixing portion 120 is attached. In this way, the eaves through hole 222b is separated from the position where the fixing portion 120 is attached.

In this embodiment 1, the base connection part 223b and the eaves connection part 223c have the function of the connection part 223d that connects the base part 221 and the eaves part 222 via the fin part 223. The base connection part 223b fixes the fin 223a to the base part 221, and the eaves connection part 223c fixes the fin 223a to the eaves part 222. In this embodiment 1, the base connection part 223b and the eaves connection part 223c are provided on all pairs of fins 223a, and all pairs of fins 223a are fixed to the base part 221 and the eaves part 222. Therefore, the base part 221, the fin 223a, and the eaves part 222 are in close contact with each other, and the heat transfer can be improved. Note that the base connection part 223b and the eaves connection part 223c may be provided on at least one of the multiple fins 223a. If the base connection portion 223b and the eaves connection portion 223c are provided only on a portion of the fin 223a, the manufacturing process for the heat sink 220 is reduced and assembly is easy. In addition, the base connection portion 223b and the eaves connection portion 223c do not need to be provided on the fin 223a and may be separate members.

Furthermore, in this embodiment 1, the base portion 221, the fin portion 223, and the eaves portion 222 are illustrated as being formed by processing an aluminum plate, but a part of the heat sink 220 may be formed by injection molding. In this case, the heat sink 220 is manufactured by combining a portion formed by processing the aluminum plate with a portion formed by injection molding. Also, in this embodiment 1, the fins 223a are illustrated as being arranged radially on the base portion 221, but they may be arranged in parallel with each other.

(Light source fixture 215)
FIG. 13 is a side view showing the light source fixture 215 according to the first embodiment of the present invention. The light source fixture 215 fixes the light source unit 210 to the heat sink 220, and has a head 215a, a columnar portion 215b, and a screw portion 215c as shown in FIG. 13. The head 215a is, for example, conical, and contacts the surface of the light distribution control member 214 to press the light distribution control member 214 toward the heat sink 220. The columnar portion 215b is, for example, cylindrical, and is connected to the head 215a. The columnar portion 215b is inserted into the tube portion 214b formed in the light distribution control member 214. The diameter of the columnar portion 215b is approximately equal to the diameter of the tube portion 214b. As a result, the columnar portion 215b is inserted into the tube portion 214b and can rotate, suppressing the light source unit 210 from moving in the radial direction (horizontal direction).

The height of the columnar portion 215b is higher than the height of the tube portion 214b of the light distribution control member 214. This makes it possible to prevent the head portion 215a from pressing the light distribution control member 214 when the screw portion 215c is screwed into the heat sink 220. If the light distribution control member 214 is made of resin, the height of the columnar portion 215b is designed taking into consideration the thermal expansion and contraction of the light distribution control member 214. The diameter of the columnar portion 215b is longer than the diameter of the substrate fixing hole 212a. Therefore, the columnar portion 215b is not inserted into the substrate fixing hole 212a. Therefore, the head portion 215a can press the substrate 212 against the heat sink 220 without pressing the light distribution control member 214.

The screw portion 215c is connected to the columnar portion 215b, inserted into the board fixing hole 212a formed in the board 212, and screwed into the light source fixing hole 221c formed in the heat sink 220. This allows the light source fixing device 215 to fix the light source unit 210 to the heat sink 220.

Figures 14 to 16 are perspective views of the heat sink 220 and the light source unit 210 according to the first embodiment of the present invention during assembly. Next, the process of attaching the light source unit 210 to the heat sink 220 will be described. As shown in Figure 14, the notch 212b formed in the substrate 212 faces the bush 250 of the base unit 221 of the heat sink 220. Also, the claw portion 214c of the light distribution control member 214 faces the recessed portion 221b of the base unit 221. Furthermore, the tube portion 214b of the light distribution control member 214 faces the light source fixing hole 221c of the base unit 221. Then, as shown in Figure 15, the bush 250 is fitted into the notch 212b, the claw portion 214c is accommodated in the recessed portion 221b, and the light source fixing hole 221c and the tube portion 214b communicate with each other. As a result, the light source unit 210 and the heat sink 220 come into contact with each other.

The bush 250 has a function of positioning the light source unit 210 and the heat sink 220, and also suppresses the rotation of the light source unit 210. Then, as shown in FIG. 16, the columnar portion 215b and the screw portion 215c of the light source fixing device 215 are inserted into the tube portion 214b, and the screw portion 215c is screwed into the light source fixing hole 221c, and the light source unit 210 is fixed to the heat sink 220. In addition, in the base portion 221, the claw portion 214c is accommodated in the recess 221b, so that the back surface of the substrate 212 and the heat sink 220 can be closely attached to each other. This can improve the heat dissipation efficiency.

(Power supply unit 230)
The power supply unit 230 is provided on the eaves portion 222 of the heat sink 220, so that heat generated from the power supply unit 230 can be transferred to the heat sink 220. Therefore, the heat sink 220 can suppress an increase in temperature of the power supply unit 230. As shown in Figs. 1 and 2, the power supply unit 230 has a lighting device 231, a terminal block 232, a main body bottom portion 233, a main body lid portion 234, a terminal block cover 235, and a power supply side connector 236. The lighting device 231 supplies power for lighting to the light source portion 210 via an electric wire 260. The terminal block 232 is connected to an electric wire 260 from a commercial power source provided outside, and supplies power to the lighting device 231.

The main body bottom 233 is for placing the lighting device 231 and the terminal block 232, and is attached to the second eaves surface 22b of the eaves portion 222 of the heat sink 220. The main body cover 234 is attached to the main body bottom 233 so as to cover the lighting device 231 and the terminal block 232. As a result, the lighting device 231 and the terminal block 232 are stored inside the case consisting of the main body cover 234 and the main body bottom 233. The terminal block 232 is exposed to the outside from an opening formed in the main body cover 234. The terminal block cover 235 is a member that covers the input portion 2231 of the terminal block 232 exposed from the opening of the main body cover 234. The power supply side connector 236 protrudes from the main body cover 234 and is covered by the terminal block cover 235. The power supply side connector 236 receives a signal from the functional unit 1000 and connects to the lighting device 231.

(Cover 240)
FIG. 17 is a perspective view showing the cover 240 according to the first embodiment of the present invention. As shown in FIG. 17, the cover 240 is a box body in the shape of a rectangular cylinder with a bottom, and is fixed to the base part 221 of the heat sink 220 while covering the light source part 210. The cover 240 is fixed to the heat sink 220 by a cover fixing screw 242. The cover 240 has a cover protrusion part 241, and the cover protrusion part 241 is provided, for example, eight pieces on the inside of the cover 240, and contacts the end part of the light source part 210. The cover protrusion part 241 has a function of preventing the light source part 210 from falling. In addition, the cover protrusion part 241 may be configured to press the light source part 210 toward the heat sink 220, thereby further improving the heat dissipation. In this way, the light source unit 200 is assembled by fixing the light emitting part 213 to the light distribution control member 214 and fixing the light source part 210 with the light emitting part 213 attached to the light distribution control member 214 to the heat sink 220. Therefore, the light source unit 200 can be easily assembled.

A lens 214a unit that controls the direction of travel of light irradiated from the light source unit 210 and a reflector that reflects the light may be provided inside the cover 240. When the lens 214a unit is provided, it is preferable that the light source unit 210 and the lens 214a unit are fixed to the heat sink 220 after being integrated. This prevents the relative positions of the light emitting element 211 of the light source unit 210 and the lens 214a of the lens 214a unit from shifting, improving the ease of assembly of the lighting device 1.

Figure 18 is a side cross-sectional view showing the fixing part 120 according to the first embodiment of the present invention, and is a cross-sectional view taken along the line A-A in Figure 4. Here, the fixing part 120 will be described in detail. As described above, the fixing part 120 is made of a metal having rigidity. As shown in Figure 13, the fixing part 120 abuts against the first overhanging surface 22a of the overhanging part 222 of the heat sink 220, and embraces the cover 240 to engage with the heat sink 220, thereby reducing the stress load on the screws caused by vibrations, etc., and supplementing the strength.

Here, the base connection part 223b and the eaves connection part 223c, which are the connecting part 223d, connect the base part 221 and the eaves part 222 through the fin part 223. Therefore, the heat from the light source part 210 can be transferred to the eaves part 222 through the fin part 223. Therefore, even if the eaves part 222 is provided in the heat sink 220, the heat dissipation can be maintained. Conventionally, when the eaves part is provided on the heat sink, the heat dissipated from the heat sink is blocked by the eaves part, and the heat is trapped, and the heat dissipation performance is deteriorated. In addition, if the distance between the tip of the fin and the eaves part is widened to prevent the heat from being trapped, the lighting device becomes large. In contrast, in the present embodiment 1, the eaves part 222 is formed by processing an aluminum plate with high heat dissipation, so there is no need to provide a distance between the eaves part 222 and the fin 223a. Therefore, the heat sink 220 can contact the eaves part 222 and the fin 223a. Therefore, the heat sink 220 can reduce the size of the lighting fixture 1 while maintaining heat dissipation properties.

(Functional Unit 1000)
Fig. 19 is an assembled perspective view showing a functional unit 1000 according to the first embodiment of the present invention, and Fig. 20 is an exploded perspective view of the functional unit 1000 according to the first embodiment of the present invention as viewed from the front side. Fig. 21 is an exploded perspective view of the functional unit 1000 according to the first embodiment of the present invention as viewed from the rear side. Next, the functional unit 1000 will be described. As shown in Figs. 19 to 21, the functional unit 1000 has a functional connecting part 1100 that is fixed to the heat sink 220 using a unit fixing tool 1101, and a functional part 1200 that is fixed to the functional connecting part 1100.

The functional connection part 1100 is formed by bending a conductive sheet metal member. The functional connection part 1100 has an attachment surface 1110, a first protruding part 1120, a second protruding part 1130, a connection piece 1131, and a harness protection part 1140. The attachment surface 1110 is a member to which the functional part 1200 is attached. The attachment surface 1110 has an antenna opening 1111 and a harness opening 1112. The antenna opening 1111 is formed below the first protruding part 1120, so that no metal is present in the part facing the antenna 1212 of the functional part 1200. The harness opening 1112 is formed above the second protruding part 1130, and communicates with the inside of the harness protection part 1140, through which the harness 1141 is inserted.

The first protrusion 1120 extends from the lower part of the mounting surface 1110 in a direction substantially perpendicular to the mounting surface 1110 and engages with the second base surface 21b of the base part 221. The second protrusion 1130 extends from the upper part of the mounting surface 1110 in a direction substantially perpendicular to the mounting surface 1110 and engages with the second eaves surface 22b of the eaves part 222. The distance between the lower end of the first protrusion 1120 and the upper end of the second protrusion 1130 is substantially equal to the distance between the base part 221 and the eaves part 222 of the heat sink 220. The connecting piece 1131 is a member extending in a vertical direction from the upper end of the second protrusion 1130 and is connected to the eaves part 222 by the unit fixing device 1101. The connecting piece 1131 has a unit fixing hole 1132 into which the unit fixing device 1101 is inserted. Here, the unit fixing device 1101 is inserted into the unit fixing hole 1132 and the eaves through hole 222b formed in the eaves portion 222 to fix the heat sink 220 and the functional unit 1000.

The harness protection section 1140 is provided at the upper end of the mounting surface 1110, and houses and protects the harness 1141 that connects the functional section 1200 and the power supply unit 230. Here, the harness 1141 has a first connection section 1142 at one end that is detachably connected to the functional section 1200, and a second connection section 1143 at the other end that is detachably connected to the power supply side connector 236. Note that the harness 1141 does not need to be detachably connected, and may be drawn out from either the functional section 1200 or the power supply unit 230.

The functional unit 1200 receives signals from the outside via wireless communication, converts the received signals, and outputs them to the power supply unit 230. The functional unit 1200 has a wireless module 1210 and a case 1240. The wireless module 1210 has a functional board 1211, an antenna 1212, a signal conversion unit 1213, a setting unit 1214, and a connector unit 1215. The functional board 1211 is a rectangular plate-shaped member. The antenna 1212 is provided at the bottom of the functional board 1211, and receives signals from the outside. The signal conversion unit 1213 is provided at the top of the antenna 1212 on the functional board 1211, and converts the signals received by the antenna 1212.

The setting section 1214 is provided on the functional board 1211 above the signal conversion section 1213, and is used to set each function of the functional unit 1000. Two connector sections 1215 are provided on the upper end of the functional board 1211, and the first connection section 1142 of the harness 1141 is connected to the connector sections 1215. The wireless module 1210 outputs the signal converted by the signal conversion section 1213 from the connector sections 1215 via the harness 1141 to the power supply unit 230. The functional board 1211 has a board mounting hole 1211a formed therein.

The case 1240 houses the functional substrate 1211 and has a case body 1220 and a case lid 1230. The case body 1220 is formed, for example, from a resin material, and is attached to the mounting surface 1110 of the functional connecting part 1100. The case body 1220 is box-shaped and has a protruding piece 1221 extending from the surface facing the functional substrate 1211. The wireless module 1210 is fixed to the case body 1220 by inserting the protruding piece 1221 into the substrate mounting hole 1211a.

The case lid 1230 is formed, for example, from a resin material, and is attached to the case body 1220 so as to cover the wireless module 1210. The case lid 1230 has an operation opening 1231 formed at a position facing the setting unit 1214, and a user can operate the setting unit 1214 from the outside through the operation opening 1231. The case lid 1230 has a plurality of lid-side protrusions 1232 extending from the surface facing the functional substrate 1211, and the plurality of lid-side protrusions 1232 press the substrate 212.

Here, when the functional unit 1200 is attached to the functional connection unit 1100 by the two functional fixing devices 1201, the antenna opening 1111 and the antenna 1212 face each other across the functional board 1211 and the case body 1220. This means that the rear side of the antenna 1212 does not directly face the conductive functional connection unit 1100. This improves the reception of the antenna 1212. Note that the functional unit 1200 and the functional connection unit 1100 are fixed by the functional fixing device 1201, but the position of the functional fixing device 1201 may be changed as appropriate. Also, instead of the functional fixing device 1201, a claw may be provided on either the functional unit 1200 or the functional connection unit 1100 to engage with each other to fix the functional unit 1200 and the functional connection unit 1100.

Two connectors 1215 are mounted on the functional board 1211, which allows signals to be output to two power supply units 230. For example, if the lighting fixture 1 has two light source units 200, the two connectors 1215 can output signals to the power supply units 230 corresponding to the two light source units 200 individually. In this way, one functional unit 1000 is connected to multiple power supply units 230, which can prevent the lighting control states of the multiple light source units 200 from differing in the receiving state of the functional unit 1000, causing a time difference in lighting. If a functional unit 1000 is provided for each power supply unit 230, there is a risk that the lighting control state will cause differences in reception in each functional unit 1000. If there is one light source unit 200, there may be only one connector 1215.

Figures 22 to 24 are perspective views of the functional unit 1000 according to the first embodiment of the present invention when it is attached. Next, the process of attaching the functional unit 1000 to the heat sink 220 will be described. As shown in Figure 22, when the functional unit 1000 is attached to the heat sink 220, the terminal block cover 235 rotates counterclockwise to expose the power supply side connector 236. Then, as shown in Figure 23, the lower end of the first protrusion 1120 faces the second base surface 21b of the base portion 221, and the upper end of the second protrusion 1130 faces the second eaves surface 22b of the eaves portion 222. In this state, the functional unit 1000 is inserted from the side of the heat sink 220. Here, the second connection portion 1143 of the harness 1141 is connected to the power supply side connector 236.

The eaves portion 222 is inserted between the second protrusion portion 1130 and the harness protection portion 1140. Then, as shown in FIG. 24, the terminal block cover 235 rotates clockwise to cover the power supply side connector 236 and the harness 1141. With the functional unit 1000 inserted into the heat sink 220, the functional fixing device 1201 is fastened and fixed to the unit fixing hole 1132 of the connection piece 1131 through the eaves through hole 222b.

As described above, the functional unit 1000 is inserted from the side of the heat sink 220 and attached to the heat sink 220. Therefore, when the functional unit 1000 is attached, there is no need to remove the light source unit 210, etc. This makes it easy to attach the functional unit 1000.

The heat sink 220 has a base portion 221 and a eaves portion 222. Therefore, by being inserted between the base portion 221 and the eaves portion 222, the functional unit 1000 is engaged with the heat sink 220, and the functional unit 1000 can be easily attached to the heat sink 220 simply by fixing with the functional fixing device 1201. The functional fixing device 1201 also fastens to the unit fixing hole 1132 formed in the connecting piece 1131 of the sheet metal material, sandwiching the eaves through hole 222b, to fix the functional unit 1000. Therefore, the functional unit 1000 can be made into a heat sink 220 while suppressing the load on the eaves portion 222 caused by fastening to the aluminum material.

Here, the eaves through hole 222b is provided on the side perpendicular to the side of the eaves part 222 to which the fixing part 120 is attached. Therefore, the functional unit 1000 is fixed to the heat sink 220 so as to be perpendicular to the fixing part 120. Therefore, when the lighting fixture 1 swings, it is possible to prevent the functional unit 1000 from interfering with other members such as the arm 110. Furthermore, the harness 1141 of the functional unit 1000 is housed inside the harness protection part 1140 formed of sheet metal, and the power supply side connector 236 is covered by the terminal block cover 235. Therefore, even if the functional unit 1000 is added later, the harness 1141 connecting the functional part 1200 and the power supply unit 230 can be protected.

Figure 25 is a side cross-sectional view of the functional unit 1000 according to the first embodiment of the present invention. As shown in Figure 25, when the functional unit 1000 is attached to the heat sink 220, the antenna 1212 is positioned on the irradiation direction side of the base portion 221 of the heat sink 220 in the optical axis direction of the light source portion 210. In other words, the heat sink 220 is not present on the rear side of the antenna 1212. Therefore, the sensitivity of wireless communication in the antenna 1212 can be maintained.

The functional connecting part 1100 fixes the upper and lower parts of the functional part 1200 with two functional fixing devices 1201, but the attachment position of the functional fixing devices 1201 can be changed as appropriate. If the lower side of the functional part 1200 is not fixed, the part below the first protruding part 1120 (below the dotted line D in FIG. 25) may be omitted so as not to cover the rear side of the antenna 1212. Also, instead of the functional fixing devices 1201, the functional part 1200 may be fixed by engagement with a claw or the like, or by adhesion.

Here, the wireless control will be described. The wireless module 1210 of the functional unit 1000 is connected to a power supply circuit that supplies power to the light source of the lighting fixture 1, for example. At this time, the power supply circuit is generally housed in a metal housing from the viewpoint of safety measures, etc. Since metal blocks radio waves, the wireless module 1210 is placed on the outer surface of the metal housing. However, if a metal housing is nearby, it may affect the reception of radio waves. In addition, if the power supply device, which is a metal housing, is separate from the main body of the lighting fixture 1, the position and posture (installation direction) at which the metal housing is installed are determined by the construction company. For this reason, it is difficult for the user to manage the installation position of the wireless module 1210, and depending on the installation state, there is a risk of a decrease in communication performance. In the present embodiment 1, since there is no metal material on the back side of the antenna 1212, the decrease in the reception of the antenna 1212 can be suppressed regardless of the construction.

Next, wireless communication will be described. The wireless module 1210 is an example of a wireless communication unit that receives a control signal for controlling the operation of the lighting fixture 1 by performing wireless communication. The control signal is, for example, a wireless signal transmitted from a mobile terminal that is an operation terminal such as a remote control or a smartphone operated by a user. The wireless module 1210 may have not only a receiving function but also a transmitting function. For example, the wireless module 1210 transmits the received control signal to another lighting fixture, etc. That is, the wireless module 1210 may have a relay function for transmitting a control signal from an operation terminal to another lighting fixture 1. This allows the control signal transmitted from the operation terminal to be received by a lighting fixture 1 that is distant from the operation terminal. Here, a lighting fixture 1 that is distant from the operation terminal refers to, for example, a lighting fixture 1 that is not located within the communication range of the operation terminal.

Note that wireless communication is communication using radio waves excluding visible light and infrared light. The wireless module 1210 performs wireless communication based on a wireless communication standard such as Wi-Fi (registered trademark), Bluetooth (registered trademark), or ZigBee (registered trademark). The wireless communication module is electrically connected to the power supply unit 230 and receives a lighting control signal for controlling the turning on or off of the lighting fixture 1. The wireless module 1210 may receive a lighting control signal for controlling the dimming or color adjustment of the lighting fixture 1. For example, the lighting control signal includes a turn-on instruction to turn on the lighting fixture 1, a turn-off instruction to turn off the lighting fixture 1, or an instruction to select the dimming ratio or color temperature of the lighting fixture 1.

Embodiment 2.
Fig. 26 is an assembled perspective view showing a functional unit 1300 according to a second embodiment of the present invention, and Fig. 27 is an exploded perspective view showing the functional unit 1300 according to the second embodiment of the present invention. The second embodiment differs from the first embodiment in that the functional unit 1300 performs wired communication instead of wireless communication. The functional unit 1300 according to the second embodiment can be attached in the same manner as the functional unit 1000 according to the first embodiment.

26 and 27, the functional unit 1300 has a functional connection part 1100 similar to that of the first embodiment, and a functional part 1500 fixed to the functional connection part 1100. The functional part 1500 receives a signal from the outside by wired communication, converts the received signal, and outputs it to the power supply unit 230. The functional part 1500 has a wired module 1410 and a case 1440. The wired module 1410 has a functional board 1411, a terminal block 1412, a signal conversion part 1413, and a connector part 1415. The functional board 1411 is a rectangular plate-shaped member. The electric wire 260 from the outside is inserted into the terminal block 1412. The terminal block 1412 is provided at the bottom of the functional board 1411, and the terminal block insertion port 1412a faces diagonally downward, which makes it easy to insert the electric wire 260 from the outside.

The signal conversion unit 1413 is provided on the upper part of the terminal block 1412 on the functional board 1411, and converts the signal received by the terminal block 1412. Two connector units 1415 are provided on the upper end part of the functional board 1411, and the first connection unit 1142 of the harness 1141 is connected to the connector units 1415. The wired module 1410 outputs the signal converted by the signal conversion unit 1413 from the connector units 1415 via the harness 1141 to the power supply unit 230. The functional board 1411 has a board mounting hole 1411a formed therein.

The case 1440 houses the functional board 1411 and has a case body 1420 and a case lid 1430. The case body 1420 is formed, for example, from a resin material, and is attached to the mounting surface 1110 of the functional connection part 1100. The case body 1420 is box-shaped and has a protruding piece 1421 extending from the surface facing the functional board 1411. The wired module 1410 is fixed to the case body 1420 by inserting the protruding piece 1421 into the board mounting hole 1411a.

The case lid 1430 is formed of, for example, a resin material, and is attached to the case body 1420 so as to cover the wired module 1410. The case lid 1430 has a terminal block opening 1431 formed at a position opposite the terminal block 1412, and the electric wire 260 inserted into the terminal block insertion port 1412a extends to the outside through the terminal block opening 1431. The case lid 1430 has a plurality of lid side protrusions 1432 extending from the surface opposite the functional board 1411, and the plurality of lid side protrusions 1432 press the board 212. The lid side protrusions 1432 are the same as the lid side protrusions 1232 in the first embodiment.

In the functional unit 1300, the terminal block insertion port 1412a faces diagonally downward in the terminal block 1412, so the electric wire 260 can be inserted into the terminal block insertion port 1412a from below. This makes it easy to insert the electric wire 260 in the functional unit 1300. Also, because the terminal block insertion port 1412a faces diagonally downward, dust is less likely to accumulate on the electric wire 260. Note that the functional connection section 1100 of the functional unit 1300 can be the same as that of the first embodiment, so that the components can be shared, but the antenna opening 1111 may be omitted.

Embodiment 3.
Fig. 28 is an assembled perspective view showing a functional section 1500 according to the third embodiment of the present invention, and Fig. 29 is an exploded perspective view showing the functional section 1500 according to the third embodiment of the present invention. The functional unit 1000 according to the third embodiment differs from the first and second embodiments in that the antenna 1532 is spaced further apart in the horizontal direction than in the first and second embodiments.

As shown in Figures 28 and 29, the functional section 1500 has a wireless module 1530 and a case 1540. The wireless module 1530 has a functional board 1531, an antenna 1532, a signal conversion section 1533, and a setting section 1534. The functional board 1531 is a square-shaped member. The antenna 1532 is attached to the functional board 1531 and receives signals from the outside. The signal conversion section 1533 converts the signal received by the antenna 1532. The setting section 1534 is used to set each function of the functional unit 1000.

The case 1540 houses the functional substrate 1531, and has a first case 1510 and a second case 1520. The first case 1510 covers the upper side of the functional substrate 1531, and the second case 1520 covers the lower side of the functional substrate 1531. Here, the second case 1520 has an operation opening 1535 formed at a position opposite the setting unit 1534, and the user can operate the setting unit 1534 from the outside through the operation opening 1535. In addition, the case 1540 houses the functional substrate 1531 so that the antenna 1532 is located below the base portion 221 when the functional substrate 1531 is housed therein.

Here, in the functional unit 1500, the second case 1520 houses the wireless module 1530 so that the wireless module 1530 is arranged vertically to the mounting surface 1110 of the functional connecting unit 1100. That is, the functional board 1531 is arranged in a direction extending horizontally from the functional connecting unit 1100. Also, the antenna 1532 is arranged at a position furthest from the functional connecting unit 1100. This moves the antenna 1532 away from the metal member, thereby suppressing interference with communication. Therefore, it is possible to suppress a decrease in the communication performance of the lighting fixture 1.

Figure 30 is a side view of the lighting device 1 according to the third embodiment of the present invention. As shown in Figure 30, the functional unit 1500 is attached to the lower part of the functional connection unit 1100. In this way, the functional unit 1500 according to the third embodiment is miniaturized, so that the entire lighting device can be miniaturized. Note that the functional units 1200, 1400, and 1500 according to the first to third embodiments are not limited to the wireless module 1530 or the wired module 1410, but may be a control board provided with a human sensor or an illuminance sensor, etc. Also, only the antenna 1532 may be housed in the case 1540, and the control member may be housed in the power supply unit 230 and connected by a coaxial cable, etc.

Embodiment 4.
Fig. 31 is a perspective view showing a lighting fixture 1a according to embodiment 4 of the present invention. As shown in Fig. 31, embodiment 4 differs from embodiment 1 in which lighting fixture 1 is a substantially rectangular parallelepiped in that base portion 221a, eaves portion 222a, and cover 240a of heat sink 220a are circular.

Here, the substrate 212 is disk-shaped. Therefore, a cylindrical heat sink 220a having a circular base portion 221a and a eaves portion 222a can be placed on the substrate 212. That is, the substrate 212 can be used as a common component whether the heat sink 220a is cylindrical or prismatic. As in the fourth embodiment, the lighting fixture 1a achieves the same effect as the lighting fixture 1 of the first embodiment, even if the base portion 221a, the eaves portion 222a, and the cover 240a of the heat sink 220a are circular.

Embodiment 5.
FIG. 32 is a perspective view showing an arm 1600 according to the fifth embodiment of the present invention. As shown in FIG. 32, in the fifth embodiment, the arm 1600 has a fixing surface 1610, an arm side surface 1620, and a rising portion 1611. The fixing surface 1610 is a rectangular member that is attached to the attached portion and extends in the horizontal direction. The arm side surface 1620 is a plate-shaped member that extends from both ends of the fixing surface 1610 in the longitudinal direction in the opposite direction to the attached portion, and is connected to the fixed portion 120 by the connecting portion 130. Here, the width of the arm side surface 1620 at a position separated from the portion connected to the fixed portion 120 is narrow. This allows the arm side surface 1620 to be made lighter. In addition, since the width of the portion connected to the fixed portion 120 is wide in the arm side surface 1620, the connectivity with the fixed portion 1800 is not deteriorated. The rising portion 1611 is a member that rises from both ends of the short side of the fixing surface 1610 to the opposite side to the attached portion. This allows the strength of the fixing surface 1610 to be improved.

Embodiment 6.
Fig. 33 is an assembled perspective view showing a heat sink 220 according to the sixth embodiment of the present invention. As shown in Fig. 33, in the sixth embodiment, the heat sink 220 has a reinforcing fin 1700. The reinforcing fin 1700 is provided between the fins 223a and arranged so as to be perpendicular to the fixed portion 120. The reinforcing fins 1700 are provided in pairs, and the opposing direction of the reinforcing fins 1700 provided in the pair intersects with the opposing direction of the fixed portion 120 provided in the pair, and is, for example, perpendicular.

34 is an exploded perspective view of the heat sink 220 according to the sixth embodiment of the present invention, viewed from below. As shown in FIG. 34, the reinforcing fin 1700 is a plate-like member that extends from the base portion 221 toward the eaves portion 222 and has the same height as the fin 223a. The reinforcing fin 1700 has a short-side flange 1701 that extends vertically from both ends in the short direction, and a long-side flange 1702 that extends vertically from both ends in the long direction. The long-side flange 1702 has a mounting hole 1703, and the mounting hole 1703 is used to fix one of the long-side flanges 1702 to the base portion 221, and the other long-side flange 1702 to the eaves portion 222. As a result, the reinforcing fin 1700 is connected to the base portion 221 and the eaves portion 222, respectively. As a result, the reinforcing fin 1700 improves the connection strength between the base portion 221 and the eaves portion 222.

In addition, the reinforcing fin 1700, together with the fixing portion 120, can mainly suppress deformation due to a torsional load, which is a rotational load in the horizontal direction of the fin 223a (a direction perpendicular to the direction in which the base portion 221 and the eaves portion 222 face each other), and a horizontal load. Therefore, the reinforcing fin 1700 can suppress deformation of the fin portion 223. Therefore, it is possible to suppress a decrease in heat dissipation performance due to deformation of the fin portion 223. Therefore, it is possible to maintain the light emission performance of the light source portion 210. Since the heat sink 220 of the first to fifth embodiments has the base portion 221 and the eaves portion 222, the reinforcing fin 1700 can be easily added as in the sixth embodiment, and the heat dissipation performance can be improved. Furthermore, since the heat sink 220 according to the first to sixth embodiments is detachable, various additional parts can be added and attached after installation.

Figure 35 is a perspective view showing fin 223a according to embodiment 6 of the present invention. As shown in Figure 35, fin 223a has protrusion 2230 that protrudes in a direction intersecting the direction extending from base portion 221 toward eaves portion 222. This improves the strength of fin 223a. In embodiment 6, protrusion 2230 is provided at the upper end of fin 223a, but protrusion 2230 may be provided at any part of fin 223a.

Embodiment 7.
FIG. 36 is an assembled perspective view showing a lighting device 1b according to the seventh embodiment of the present invention. As shown in FIG. 36, the lighting device 1b according to the seventh embodiment has two light source units 200, and the fixing portion 1800 connects and fixes the two light source units 200. The fixing portion 1800 is a plate-shaped member extending in the horizontal direction, and connects the first base surface 21a of the base portion 221 of each of the two light source units 200 to the first eaves surface 22a of the eaves portion 1222. In this way, the lighting device 1b according to the seventh embodiment can connect a plurality of light source units 200 simply by changing the fixing portion 1800. Note that, in the seventh embodiment, the fixing portion 1800 connects two light source units 200 as an example, but the fixing portion 1800 may connect three or more light source units 200.

Figure 37 is an exploded perspective view showing a lighting fixture 1b according to embodiment 7 of the present invention. As shown in Figure 37, the two eaves parts 1222 in embodiment 7 are integrally formed. This can improve the strength of the heat sink 220. Note that three or more eaves parts 1222 may be integrally formed.

1, 1a, 1b Lighting fixture, 21a First base surface, 21b Second base surface, 22a First eaves surface, 22b Second eaves surface, 100 Support portion, 110 Arm, 120 Fixing portion, 130 Connection portion, 140 Fall prevention portion, 141 Wire, 142 Mounting portion, 200 Light source unit, 210 Light source portion, 211 Light emitting element, 212 Substrate, 212a Substrate fixing hole, 212b Notch, 212c Substrate engagement hole, 213 Light emitting portion, 214 Light distribution control member, 214a Lens, 214b Tube portion, 214c Claw portion, 215 Light source fixing device, 215a Head portion, 215b Columnar portion, 215c Screw portion, 220, 220a Heat sink, 221, 221a Base portion, 221b Recess, 221c light source fixing hole, 221d cover fixing hole, 222, 222a eaves portion, 222b eaves through hole, 223 fin portion, 223a fin, 223b base connection portion, 223c eaves connection portion, 223d connection portion, 230 power supply unit, 231 lighting device, 232 terminal block, 233 main body bottom portion, 234 main body lid portion, 235 terminal block cover, 236 power supply side connector, 240, 240a cover, 241 cover protrusion portion, 242 cover fixing screw, 250 bush, 260 electric wire, 1000 functional unit, 1100 functional connection portion, 1101 unit fixing tool, 1110 mounting surface, 1111 antenna opening, 1112 harness opening, 1120 first protrusion portion, 1130 Second protrusion, 1131 Connection piece, 1132 Unit fixing hole, 1140 Harness protection part, 1141 Harness, 1142 First connection part, 1143 Second connection part, 1200 Functional part, 1201 Functional fixing tool, 1210 Wireless module, 1211 Functional board, 1211a Board mounting hole, 1212 Antenna, 1213 Signal conversion part, 1214 Setting part, 1215 Connector part, 1220 Case main body part, 1221 Protrusion piece, 1222, Eaves part, 1230 Case lid part, 1231 Operation opening, 1232 Lid side protrusion, 1240 Case, 1300 Functional unit, 1400 Functional part, 1410 Wired module, 1411 Functional board, 1411a Board mounting hole, 1412 Terminal block, 1412a Terminal block insertion port, 1413 signal conversion section, 1415 connector section, 1420 case main body section, 1421 protruding piece, 1430 case lid section, 1431 terminal block opening, 1432 lid side protruding section, 1440 case, 1500 functional section, 1510 first case, 1520 second case, 1530 wireless module, 1531 functional board, 1532 antenna, 1533 signal conversion section, 1534 setting section, 1535 operation opening, 1540 case, 1600 arm, 1610 fixing surface, 1611 rising section, 1620 arm side, 1700 reinforcing fin, 1701 short side flange, 1702 long side flange, 1703 mounting hole, 1800 fixing section, 2230 protruding section, 2231 Input section.

Claims (1)

A light-emitting element;
a substrate on which the light emitting element is mounted and on which a substrate engagement hole is formed;
a light distribution control member having a claw portion protruding toward the substrate, the claw portion engaging with the substrate engaging hole, the light distribution control member being attached to the substrate so as to cover the light emitting element, and controlling the light distribution of light emitted from the light emitting element;
a base portion having a recess on one surface to which the substrate is attached and into which the claw portion of the light distribution control member is housed;
a fin portion provided substantially perpendicularly on a back surface of the base portion opposite to the one surface;
Equipped with
the recess is formed on a pedestal at a portion of the base portion that contacts the substrate,
The plurality of recesses are connected in a substantially doughnut shape.
Light source unit.

Images