JP2019200870A - Heat sink and illuminating device - Google Patents

Abstract

To provide a heat sink that can restrain an increase in weight, and an illuminating device that comprises the heat sink.SOLUTION: A heat sink 100 comprises a base part 110, and a plurality of fin parts 120. Each of the fin parts 120 comprises: a fin main part 121 formed in a plate shape rising from the base part 110, and comprising one side part 121a along a rising direction 120a, and another side part 121b along the rising direction 120a; and three branch parts 122 branching from the other side part 121b of the fin main part 121, and extending so as to separate from one another as going in a direction from the one side part 121a to the other side part 121b.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a heat sink and a lighting device using the heat sink.

Conventionally, there is a lighting fixture using a heat sink in order to efficiently dissipate heat from a light source such as an LED. The heat sink increases heat radiation area by a plurality of heat radiation fins so that heat can be efficiently radiated (for example, Patent Document 1).
However, the heat sink has a problem that it has many fins and is heavy.

JP, 2006-207368, A

  Then, it aims at provision of the heat sink which can suppress a weight increase, and the lighting fixture which has this heat sink.

The heat sink of this invention is
A base part to which a light source part is attached;
A plurality of fin portions arranged so that the base portion is positioned between the light source portion, and
Each fin part is equipped with
A fin main portion having a plate shape rising from the base portion and having one side portion along the rising direction and the other side portion along the rising direction,
A plurality of fin branch portions branched from the other side portion of the fin main portion and extending away from the one side portion toward the other side portion.

  Since the heat dissipation of the heat sink of the present invention has a plurality of fin branch portions, the number of fin branch portions can be suppressed. Therefore, according to the heat sink of the present invention, an increase in weight can be suppressed.

FIG. 3 is a perspective view of the lighting device according to the first embodiment. The perspective view seen from the downward direction Z2 of the illuminating device in the figure of Embodiment 1. FIG. FIG. 3 is an exploded perspective view of the lighting device according to the first embodiment. FIG. 3 is a detailed exploded perspective view of the lighting device in the first embodiment. FIG. 3 is a perspective view of the heat sink in the first embodiment. FIG. 3 is a diagram of the first embodiment, and is a plan view of the heat sink. In the figure of Embodiment 1, it is a perspective view of an electric wire cover part. The perspective view of the heat sink with which the electric wire cover part was attached in the figure of Embodiment 1. FIG. FIG. 3 is an exploded perspective view of the light emitting unit in the first embodiment. FIG. 3 is a diagram of the first embodiment, and is a perspective view of a cover part. FIG. 6 is another perspective view of the cover unit in the first embodiment. FIG. 3 is a diagram of the first embodiment, and is a perspective view of a frame portion. The perspective view seen from the downward direction Z2 of the power supply device in the view of the first embodiment. In the figure of Embodiment 1, it is a disassembled perspective view seen from the downward direction Z2 of a power supply device. In the figure of Embodiment 1, it is an exploded perspective view seen from the upper direction Z1 of a power supply device. FIG. 3 is a diagram of the first embodiment, and is a plan view of the lighting device. FIG. 3 is a diagram of the first embodiment, and shows a relationship between the distance L of the power supply device and the temperature of the light source. FIG. 3 is an assembly diagram illustrating the attachment of the frame portion to the cover portion in the first embodiment. The figure of Embodiment 1, The figure which shows the construction method of an illuminating device. The figure of Embodiment 1, The figure which shows a tall lighting fixture. The figure of Embodiment 1, The figure which shows the modification of a cover part. The perspective view which shows the modification of a heat sink in the figure of Embodiment 1. FIG. FIG. 5 is a diagram of the first embodiment and is a plan view of a modification example of the heat sink. The elements on larger scale of FIG. The figure of Embodiment 1, The figure which shows the heat dissipation of an aluminum material.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, the same code | symbol is attached | subjected to the part which is the same or it corresponds in each figure. In the description of the embodiments, the description of the same or corresponding parts will be omitted or simplified as appropriate.

Embodiment 1 FIG.
*** Explanation of configuration ***
The structure of the illuminating device 1 of Embodiment 1 is demonstrated. In the first embodiment, a description will be given with respect to a lighting fixture housed in a mounting hole provided in a mounted portion such as a ceiling. For example, the luminaire is a downlight.

The features of the first embodiment are particularly the cover unit 230, the heat sink 100, and the power supply device 20.
FIG. 1 is a perspective view of the lighting device 1.
FIG. 2 is a perspective view seen from the lower direction Z2 of the lighting device 1. FIG.
FIG. 3 is an exploded perspective view of the lighting device 1.
FIG. 4 is an exploded perspective view of the lighting device 1 in more detail.

  The illuminating device 1 includes a luminaire 10 provided at a mounted portion, and a power supply device 20 attached to the luminaire 10 so as to be rotatable. A portion obtained by removing the power supply device 20 from the lighting device 1 is referred to as a lighting fixture 10. As illustrated in FIG. 4, the lighting fixture 10 includes a heat sink 100, a light source unit 200 having a cover unit 230, and a frame unit 300.

(Heat sink 100)
FIG. 5 is a perspective view of the heat sink 100.
FIG. 6 is a plan view of the heat sink 100. As shown in FIGS. 5 and 6, the heat sink 100 includes a plate-like base portion 110, a fin portion 120 that rises from the base portion 110, a power supply holding portion 130, and a cord holding portion 140. The heat sink 100 is formed by press molding, and can be integrally formed by press molding. The press molding is, for example, cold forging. By using press molding, a material having a high aluminum content (for example, 99 wt% or more) can be used for the heat sink 100.

(Base part 110)
The base part 110 is a plate-like body. The light source unit 200 is attached to the base unit 110. One surface of the base part 110 is a light source attachment surface 111 to which the light source part 200 is attached. The other surface, which is the back surface of the light source mounting surface 111, is a fin placement surface 112 on which the fin portion 120 rises.
Further, the heat sink 100 has a cylindrical portion 113 that protrudes in a cylindrical shape from the center portion of the base portion 110 on the fin arrangement surface 112. The tube part 113 is provided at a position facing the back surface of the light source part 200 attached to the light source attachment surface 111.

(Fin portion 120)
The fin part 120 is demonstrated. The fin part 120 includes a fin main part 121, a fin branch part 122, and end fins 123. As shown in FIG. 6, the heat sink 100 has six fin portions 120.
Although the heat sink 100 of the first embodiment has six fin portions 120, the number of fin portions 120 is not limited to six. The heat sink 100 has a plurality of fin portions 120. The plurality of fin portions 120 are arranged such that the base portion 110 is positioned between the light source portions 200. Each fin portion 120 has a fin main portion 121 and a plurality of fin branch portions 122. In FIG. 6, three fin branch portions 122 are branched, but four or more may be branched. The fin branch portion 122 is bent at the folding portion 125. The fin main part 121 has a plate-like shape rising from the base part 110 and has one side part 121a along the rising direction 120a and the other side part 121b along the rising direction 120a. Each fin branch part 122 branches from the first branch part 126a of the other side part 121b of the fin main part 121, and extends so as to be separated from one side part 121a toward the other side 121b. In addition, the fin branch portion 122 has a plurality of end fins 123 that branch from the second branch portion 126b at the end in a direction extending away from the fin branch portion 122. In FIG. 6, two end fins 123 are branched, but three or more may be branched. In FIG. 6, the end fins 123 are formed at the ends of the 14 fin branch portions 122, but a plurality of end fins 123 may be formed at the end of at least one fin branch portion 122. In FIG. 6, two end fins 123 are branched, but the number of branched end fins 123 may be three or more.

  The fin portion 120 is provided so as to rise from the fin placement surface 112 in a substantially vertical direction, and is formed radially from the central portion of the fin placement surface 112. The fin portion 120 is provided radially outward from the tube portion 113 on the fin disposition surface 112. The fin part 120 can increase the heat radiation area by having the fin branch part 122 that branches from the fin main part 121. Since the end fin 123 is formed at the end of the fin branching portion 122, the heat radiation area of the end fin 123 increases. That is, since heat can be radiated not only from the outer surface of the fin branch portion 122 but also from the inner surface 123a of the end fin 123, the heat radiation efficiency is increased. Further, since the heat radiation efficiency can be improved by the end fins 123, the fin portions 120 can reduce the number of the fin portions 120 protruding from the fin placement surface 112, and as a result of this reduction, the fin portions 120 are adjacent to each other. It is possible to provide a large space between the fin portions 120 to be performed. The distance between adjacent fin portions 120 is, for example, about 5 mm. The distance between adjacent fin portions 120 of about 5 mm is the length of a distance L2 shown in FIG. By providing the fin branch portion 122 from the fin main portion 121, the end portions of the adjacent fin main portions 121 can be spaced apart at the center side of the base portion 110.

(Power supply holding unit 130)
In the heat sink 100, the power supply device 20 that supplies power to the light source unit 200 is attached to the power supply holding unit 130. The power supply holding unit 130 is provided so as to protrude in a substantially vertical direction from the fin disposition surface 112, and the horizontal section has an L shape. The power supply holding unit 130 is provided in a pair at the end of the fin disposition surface 112, and is provided with a holding hole 131 to which the power supply device 20 is rotatably attached.

(Cord holding unit 140)
The cord holding portion 140 is provided so as to protrude in a substantially vertical direction from the fin placement surface 112, and has a U-shaped horizontal cross section. The cord holding part 140 is disposed between the power supply holding parts 130 provided in a pair, and an electric wire that connects the power supply device 20 and the light source part 200 is arranged inside the U shape.

  The heat sink 100 is formed by press molding. The heat sink 100 is formed by press-molding an aluminum material from the Z1 side to the Z2 side. When the heat sink 100 is formed by press molding, the fins fall down due to the load of the press, so that the fins cannot be formed large. In particular, it is difficult to lengthen the fins in the horizontal direction, which is perpendicular to the direction from the Z1 side to the Z2 side, and it is difficult to provide one fin from the central portion of the base portion 110 to the outside. On the other hand, since the fin part 120 is formed of the fin branch part 122 and the end fin 123, the fin branch part 122 and the end fin 123 reinforce each other and can withstand the load of the press. Can do. Therefore, the fin part 120 can be provided from the center part of the base part 110 to the outside.

Further, as shown in FIGS. 7 and 8, an electric wire cover portion 150 is attached to the power supply holding portion 130 of the heat sink 100.
FIG. 7 is a perspective view of the electric wire cover part 150.
FIG. 8 shows the heat sink 100 with the wire cover 150 attached. The wire cover portion 150 has a shape as shown in FIG. 7 and is attached to the power supply holding portion 130 so as to close the U-shaped opening of the cord holding portion 140. The electric wire cover 150 is attached so that the electric wire does not come off from the U-shaped inner side. Moreover, the electric wire cover part 150 has the power supply control part 151 which contact | abuts the power supply device 20 at an upper end side. The power supply control unit 151 contacts a part of the power supply device 20 and controls the rotation of the power supply device 20. The power supply control unit 151 controls the rotation of the power supply device 20 so that an interval is maintained between the power supply device 20 and the heat sink 100.

(Light source unit 200)
As shown in FIG. 4, the light source unit 200 includes a light emitting unit 210, a socket unit 220 that fixes the light emitting unit 210 to the heat sink 100, and a cover unit 230.

(Light Emitting Unit 210)
FIG. 9 is an exploded perspective view of the light emitting unit 210. The light emitting unit 210 includes a light emitting element 211 and a substrate 212 on which the light emitting element 211 is mounted. In the light emitting unit 210, the light emitting element 210 may be a COB (chip on board) as shown in FIG. 9, or a plurality of package types may be used.

(Socket part 220)
The socket unit 220 illustrated in FIG. 9 supplies power from the power supply device 20 to the light emitting unit 210. The socket part 220 is fixed to the heat sink 100 with the light emitting part 210 sandwiched therebetween. The socket part 220 sandwiches the light emitting part 210 with a socket front part 221 that is opened so that the light emitting element 211 is exposed, and a socket rear part 222 that covers the back side of the substrate 212 of the light emitting part 210. Although not shown, an electric wire is connected. The light emitting unit 210 and the power supply device 20 are electrically connected via this electric wire. The socket front part 221 and the socket back part 222 are fixed by two clips 223. In the first embodiment, the light emitting unit 210 is fixed to the heat sink 100 using the socket unit 220. However, the light emitting unit 210 may be fixed to the heat sink as described in Japanese Patent No. 6158886. Good.

(Cover section 230)
10 and 11 are perspective views of the cover portion 230. The cover part 230 is integrally formed of a resin material. As will be described later, the cover portion 230 includes a claw portion 236 and a hook portion 235 having a protruding portion 235a, and is attached to the heat sink 100. The cover portion 230 has a cover main body portion 231 having a substantially central opening (cover opening portion 232) in a circular shape, and an inner wall portion 233 formed so as to stand up from the peripheral edge portion of the cover opening portion 232 of the cover main body portion 231. And an outer wall portion 234 formed so as to stand upright from the outer peripheral portion of the cover main body portion 231. Further, the cover portion 230 includes an outer wall portion 234 that protrudes so as to be elastically deformable, a claw portion 236 provided at a position facing the hook portion 235 and the cover opening 232, and an outer wall portion. A frame receiving portion 237 protruding outward from 234 is formed. Note that the hook portion 235 has a structure that is elastically deformed and hooked to the frame portion 300 in the same manner as the first convex portion 434 described in Japanese Patent No. 6158886. The cover part 230 is detachably attached to the frame part 300 in a state where the cover part 230 is attached to the base part 110 of the heat sink 100 by a fixing member such as a screw. The cover part 230 has a function of a connection part that fixes the frame part 300 to the heat sink 100.

As shown in FIG. 4, the cover 230 is provided with a light distribution controller 238 so as to cover the cover opening 232. The light distribution control unit 238 has a lens shape, and receives light from the light emitting unit 210 and emits the incident light in a predetermined direction. The light distribution control unit 238 has a lens shape as shown in FIG. However, the shape of the light distribution control unit 238 shown in FIG. 18 is an example.
If a predetermined light distribution can be obtained, the lens shape may be different from that in FIG. 18. For example, the light distribution control unit 238 may have a flat plate shape. Moreover, the method of attaching the cover part 230 may be a method of engaging with the cover main body part 231 like a light-transmitting cover, for example.

(Frame part 300)
FIG. 12 is a perspective view of the frame part 300. As will be described later, the frame part 300 is formed with a first hole forming part 351 in which a first hole 350 into which the claw part 236 is inserted is formed, and a second hole 360 into which the protruding part of the hook part 235 is inserted. And a second hole forming portion 361 whose periphery is pressed by the hooking portion 235 by the elastic force of the hooking portion that tries to return to its original shape, and is irradiated with light from the light source unit 200 Control the irradiation angle.

  As shown in FIG. 12, the frame part 300 includes a brim part 310, a rising part 320, and an inclined part 370 ((a) of FIG. 18). The flange 310 abuts against the edge of the circular embedding hole 501 formed in the attached portion 500. The rising part 320 rises from the brim part 310 in a substantially vertical direction. Three attachment springs 400 are attached to the rising portion 320. The rising portion 320 is formed with a first hole 350 and a second hole 360. The inclined portion 370 is formed in an oblique direction inside the collar portion 310 and has a circular opening 371 at a substantially central portion. The frame portion 300 may be formed as an integrally molded product made of resin.

  The above is the main configuration of the lighting fixture 10.

Next, the configuration of the power supply device 20 will be described with reference to FIGS.
FIG. 13 is a perspective view of the power supply device 20 as viewed from the lower Z2 side.
FIG. 14 is an exploded perspective view of the power supply device 20 as viewed from the lower side Z2.
FIG. 15 is an exploded perspective view of the power supply device 20 as viewed from the upper side Z1.
FIG. 16 is a plan view of the lighting device 1.

(Power supply device 20)
The power supply device 20 includes a lighting circuit board 21 that converts power from a commercial power source to light the light source unit 200, a terminal block 22 that supplies power from the commercial power source to the lighting circuit board 21, a lighting circuit board 21, and a terminal block A case main body 23 to which 22 is attached and a case lid 24 to be attached to the case main body 23 so as to cover the lighting circuit board 21 are provided. The terminal block 22 is provided with a power terminal block 22a and a dimming terminal block 22b.

(Case 25, case body 23)
The case 25 includes a case main body 23 and a case lid 24. The case main body 23 has a main body bottom surface portion 23a, a main body side surface portion 23b, and an arm 23c. The main body bottom surface portion 23a is formed such that a first plate portion 23aa facing the lighting circuit substrate 21 and a second plate portion 23ab facing the terminal block 22 are provided with a step. In FIG. 14, when the case main body portion 23 is viewed as the upper side and the case lid portion 24 is viewed as the lower side, the first plate portion 23aa is a top plate. Hereinafter, the first plate portion 23aa may be referred to as a top plate 23aa. The main body side surface portion 23 b is provided so as to protrude from the side of the main body bottom surface portion 23 a and has an engaging portion 23 ba that holds the lighting circuit board 21. The arm portion 23c is provided at the end of the main body bottom surface portion 23a opposite to the terminal block 22 side. The arm portions 23c are provided in pairs and are rotatably connected to the holding holes 131 of the power supply holding portion 130 of the heat sink 100.

(Case lid 24)
The case lid portion 24 includes a lid bottom surface portion 24a, a lid side surface portion 24b, and an inclined portion 24c. The lid bottom surface portion 24a covers the lighting circuit board 21, and the terminal block 22 is provided so as to be exposed. The lid side surface portion 24b is provided so as to protrude from the side of the lid bottom surface portion 24a so as to sandwich the main body side surface portion 23b. Further, the lid side surface portion 24 b is formed with such a length as to engage with the main body side surface portion 24 b and protrude beyond the terminal block 22. The inclined portion 24c is formed on the side opposite to the terminal base 22 side of the lid bottom surface portion 24a, and is formed obliquely toward the arm portion 23c of the main body bottom surface portion 23a. Moreover, the electric wire which connects the lighting circuit board 21 and the light source part 200 is accommodated between the main body bottom face part 23a and the inclination part 24c. This electric wire is accommodated inside the U-shape of the cord holding portion 140 of the heat sink 100 between the main body bottom surface portion 23a and the inclined portion 24c.

The power supply device 20 is provided so that the main body bottom surface portion 23a faces a part of the fin disposition surface 112 of the heat sink 100 in a plan view shown in FIG. Further, the rotation shaft 39 (FIGS. 1 and 16) of the power supply device 20 is provided inside the outer diameter of the heat sink 100. At this time, the power supply device 20 is disposed so as not to affect the heat dissipation of the heat sink 100.
FIG. 17 shows light emission by changing the distance L when the distance from the center A of the cylindrical portion 113 in the plan view shown in FIG. 16 to the end closest to the center A in the longitudinal direction of the power supply device 20 is the distance L. 6 is a graph showing a change in the temperature of COB in the section 210. The numerical value is an example. As shown in FIG. 17, in the COB as the light source unit, the temperature T with respect to the distance L from the power supply device 20 that is supplying power is represented by a function f of T = f (L). Further, the COB temperature T decreases linearly as the distance L increases, and shifts to a transition range in which the transition to the saturation state occurs, and reaches the saturation state through this transition range. The power supply device 20 is preferably attached to the heat sink 100 at a position L in the transition range. In this embodiment, the distance L is 40 mm and the power supply device 20 is attached to the heat sink 100. As shown in FIG. 17, when the distance L is 40 mm, it turns out that the power supply device 20 can be fixed to the heat sink 100 in the state in which the influence on heat dissipation was suppressed.
Further, when the distance L is further increased from 40 mm, the influence of temperature by the power supply device 20 is saturated.

  The above is the configuration of each unit of the power supply device 20. Next, the attachment process of the frame part 300 of the lighting fixture 10 is demonstrated using FIG.

(Attaching process of frame part 300)
FIG. 18 shows an attaching process for attaching the frame part 300 to the cover part 230.
FIG. 18A shows a state before the frame part 300 is attached to the cover part 230 provided on the heat sink 100.
18B shows a state where the first hole 350 (FIG. 12) of the frame portion 300 is hooked on the claw portion 236 (FIG. 10) of the cover portion 230. FIG.
FIG. 18C shows a state in which the frame portion 300 is rotated from the state of FIG. 18B with the first hole 350 into which the claw portion 236 is inserted as the axis of rotation. 18C shows a state in which the hook portion 235 (FIG. 10) is engaged with the second hole 360 (FIG. 12) of the frame portion 300. FIG.

The frame portion 300 is elastically deformed when the hook portion 235 is brought into contact with and pressed by the end portion of the rising portion 320 by the rotation of the frame portion 300, and is engaged with the second hole 360. Retained. Further, in the state of FIG. 18C, the frame portion 300 is rotated so that the end portion of the rising portion 320 (FIG. 12) is placed on the frame receiving portion 237 (FIG. 10) of the cover portion 230. It is in contact with the receiving part 237.
That is, the cover part 230 holds the frame part 300 so as to close the rising part 320 of the frame part 300.

  The frame portion 300 inserts the claw portion 236 of the cover portion 230 into the first hole 350 of the first hole formation portion 351 so that the first hole formation portion 351 is hooked on the claw portion 236 and then the second hole formation portion 361. Can be turned toward the hooking portion 235.

  The above is the attachment method for attaching the frame part 300 to the cover part 230. Next, the construction method to the to-be-attached part of the illuminating device 1 is demonstrated.

(Method of construction on the mounted portion of the lighting device 1)
FIG. 19 shows a construction method for the mounting portion of the lighting device 1.
FIG. 19A shows a state before the lighting device 1 is attached to the attachment hole 501 provided in the attached portion 500.

FIG. 19B shows a state in which the 501 power supply device 20 is inserted into the mounting hole.
The power supply device 20 is inserted into the mounting hole 501 in a state in which an electric wire 31 for receiving power supply from a commercial power source and an electric wire 31 such as a signal line are inserted into the terminal block 20. The operator rotates the power supply device 20 away from the lighting fixture 10 and inserts the lighting device 1 into the mounting hole 501. The state rotated so that it leaves | separates is the state protruded in the substantially perpendicular | vertical direction with respect to the lighting fixture 10, for example. At this time, the operator can hold both the lighting fixture 10 and the power supply device 20 with one hand. Since the power supply device 20 is connected to the heat sink 100 as a rotation shaft 39, the rotation shaft 39 can be held together with the heat sink 100, and the power supply device 20 can be attached to the mounting hole at a predetermined angle. Can be inserted. The power supply device 20 forms a holding space 32 (FIG. 19B) in which the lighting fixture 10 can be held between the inclined portion 24c and the lighting fixture 10. The operator can adjust and hold the angle of the power supply device 20 by interposing a finger in the gripping space 32 between the inclined portion 24 c and the heat sink 100. In addition, the power supply device 20 forms the holding space 32 ((b) of FIG. 19) which can hold | grip the lighting fixture 10 between the inclination part 24c and the lighting fixture 10. As shown in FIG. The operator can hold the lighting fixture 10 and the power supply device 20 with one hand. If the rotary shaft 39 is away from the heat sink, the heat sink must be held with one hand and the power supply with the other hand.

  FIG. 19C shows a state in which the luminaire 10 is inserted into the attachment hole 501, and the luminaire 10 is inserted in a state where the attachment spring 400 is hooked on the edge of the attachment hole 501. At this time, the power supply device 20 is inserted while rotating as the lighting fixture 10 is inserted.

  FIG. 19D shows a state in which the lighting fixture 10 is inserted into the mounting hole 501 and the lighting device 1 is mounted on the mounted portion 500. In the lighting fixture 10, the frame portion 300 is fixed to the mounting hole 501 by the mounting spring 400. The heat sink 100 provided with the light source unit 200 is attached to the cover unit 230. The cover part 230 to which the heat sink 100 is attached is fixed to the frame part 300 so as to be placed on the frame part 300. The power supply device 20 is installed with one end engaged with the heat sink 100 and the other end in contact with the attached portion 500.

  At this time, the other end of the power supply device 20 can provide a space in which the electric wire 31 is disposed between the terminal block 22 and the mounted portion 500 because the lid side surface portion 24 b protrudes from the terminal block 22. . By providing this space, it is possible to prevent the electric wire 31 from being pinched between the terminal block 22 and the attached portion 500 and being damaged. Moreover, when the rigid electric wire 31 is used, the lighting fixture 10 and the power supply device 20 can be prevented from being inclined due to the elastic force of the electric wire 31 (such as a restoring force caused by bending the electric wire).

  As shown in FIG. 19, the power supply device 20 is rotatably attached to the luminaire 10 attached to the attached portion 500, and is a case 25 having a top plate 23 aa and a lighting device that lights the luminaire 10. A circuit board 21 and a terminal block 22 for supplying power to the lighting circuit board 21 are provided. When the top plate 23aa is leveled along the horizontal direction 502 (FIG. 19D) of the lighting fixture 10 in a state where the lighting fixture 10 is attached to the attached portion 500, the case 25 is attached to the lighting fixture 10. It has a plate-like inclined portion 24c that is inclined so as to fall down and faces the lighting fixture 10. As shown in FIG. 2 and FIG. 19D, the terminal block 22 is disposed on the end 34 side of the virtual radius 33 when the case 25 rotates. The case 25 has a lid side surface portion 24b that forms a side surface that extends beyond the terminal block 22 in the direction of the terminal block 22 from the inclined portion 24c.

* * * Effect of heat sink 100 of Embodiment 1 * * *
(1) In the first embodiment, since the fin portion 120 is formed of the fin main portion 121 and the fin branch portion 122, the heat sink 100 can increase the surface area of the fin alone.
For this reason, heat dissipation can be improved.
(2) Further, since the number of fins 120 to be installed can be reduced by increasing the surface area of the fins alone, a space through which air can escape can be provided between adjacent fins.
(3) Moreover, since the fin part 120 is formed from the fin main part 121 and the fin branch part 122, since it can mutually reinforce, the heat sink 100 can be formed by press molding.
The press molding is, for example, by cold forging.
By molding the heat sink 100 by cold forging, the mold cost can be reduced as compared with the injection molding, and a material having a high aluminum content can be used. Therefore, a heat sink with good heat dissipation efficiency can be molded.
(4) Further, the heat sink 100 can absorb heat from the light source unit 200 by the tube unit 113 because the tube unit 113 is formed on the back side of the light source unit 200.
(5) Moreover, since the fin part 120 is connected to the cylinder part 113, the heat absorbed by the cylinder part 113 can be efficiently radiated to the atmosphere.

*** Effect of cover portion 230 of Embodiment 1 ***
(1) In the first embodiment, since the heat sink 100 includes the cover part 230 having the hook part 235 and the claw part 236, the frame part 300 can be easily attached to and detached from the cover part 230.
(2) Moreover, by using the cover part 230 used as the connection part which connects the frame part 300 to the heat sink 100, the heat sink 100 and the frame part 300 are made suitable for the output of the required light source or the light distribution of the light source. Can be changed easily.
(3) Since the hook portion 235 and the claw portion 236 are integrally formed on the cover portion 230, the frame portion 300 is fixed only by the cover portion 230 without the need for a fixing tool such as a screw. Therefore, the number of parts can be reduced.
(4) Since the claw portion 236 has a shape projecting so as to be inserted into the first hole 350 of the frame portion 300, the frame portion 300 is covered by the direction of the attachment of the frame portion 300. It can prevent attaching to the part 230 in the incorrect attachment state.
Even if an impact (for example, during construction) is applied to the frame 300, the claw 236 has a protruding shape that is inserted into the first hole 350, and therefore the claw 236 is not easily elastically deformed by the impact. The first hole 350 is difficult to come off.
(5) In addition, since the claw portion 236 has a shape protruding so as to be inserted into the first hole 350 of the frame portion 300, the size of the protruding shape does not need to be controlled as compared with the case where it is formed in a spring shape. The assembly is improved. Since the frame part 300 is held only by the cover part 230, it can be assembled even if there is an assembly tolerance when assembling the parts.
Further, since the claw portion 236 is integrated with the cover portion 230, the number of assembling steps can be reduced, and forgetting to attach components can be prevented.
(6) Moreover, since the cover part 230 has the frame receiving part 237 mounted in the edge part of the frame part 300, the hook part 235 and the nail | claw part 236 are engaged with the frame part 300 by an impact. Even if is released, the heat sink 100 can be prevented from falling because the frame receiving portion 237 is placed on the frame portion 300.
(7) Moreover, generation | occurrence | production of a squeak noise or damage of components can be suppressed by thermal expansion-contraction because the cover part 230 and the frame part 300 are formed with the resin material.

*** Effect of power supply device 20 of embodiment 1 ***
In the first embodiment, the power supply device 20 is configured such that the lighting circuit board 21 is accommodated in a case (case main body portion 23, case lid portion 24), and the case 25 is provided with an inclined portion 24c. In a state where the rotation shaft 39 is provided inside the heat sink 100, the power supply device 20 can rotate without interfering with the lighting fixture 10. That is, since it is not necessary to provide the power supply device 20 in the position away from the lighting fixture 10, the lighting fixture 1 can be reduced in size.
FIG. 20 shows a lighting fixture having a specification in which the height of the frame portion 300A is higher than that of the lighting fixture 10 of FIG. 19 and the overall height H of the lighting fixture 10 is high. Since the power supply device 20 has the inclined portion 24c and can be rotated without interfering with the lighting fixture 10, even if the height H is a high specification like the lighting fixture of FIG. The power supply device 20 can be used.

<Modification 1>
FIG. 21 is a modification of the cover part 230. FIG. 21 shows a configuration in which the cover unit 230 has a wireless function. The cover unit 230 is provided with a wire antenna 401 on the front side and accommodates a wireless substrate 402 on the back side. As shown in FIG. 21, the cover 230 accommodates the wire antenna 401 and the wireless substrate 402, so that it is not necessary to provide an opening so that the frame 300 can perform wireless communication. Therefore, since it is not necessary to prepare a wireless frame, an increase in variations of the frame can be suppressed.

<Modification 2>
(Heat sink 100a)
22, 23, and 24 show a heat sink 100 a that is a modification of the heat sink 100.
FIG. 22 is a perspective view of the heat sink 100a.
FIG. 23 is a plan view of the heat sink 100a.
24 is a partially enlarged view of FIG.
The heat sink 100a has a pedestal portion 110a. The heat sink 100a differs from the heat sink 100 in the following (1) and (2).
(1) The heat sink 100a has a pedestal portion 110a.
(2) The shape of the end fins 124 of the heat sink 100 a is different from the shape of the end fins 123 of the heat sink 100. The plurality of end fins 124 are branched at the second branch location 126b. The end fins 124 include first end fins 124a and second end fins 124b. The first end fin 124a is bent at a second bent portion 125b which is a connection portion with the second end fin 124b. Further, the second end fins 124b having the same fin branch portion 122 are arranged to face each other.

  The heat sink 100a includes a plurality of fin portions 120 and a pedestal portion 110a that protrudes from the base portion 110 at a position facing the light source portion 200 with the base portion 110 therebetween. As shown in FIG. 23, each fin portion 120 rises partially from the pedestal portion 110 a and rises from the base portion 110.

  The fin portion 120 includes a fin main portion 121 and a plurality of fin branch portions 122. Although three fin branch parts 122 are branched in FIG. 23, four or more may be branched. The plurality of fin branch portions 122 are branched at the first branch point 126a. Further, the two fin branch portions 122 are bent at the first bent portion 125a. Each fin part 120 has a plate-like shape rising from the pedestal part 110a and one side part 121a along the rising direction 120a and the other side part 121b along the rising direction 120a. As shown in FIG. 23, the plurality of fin branch portions 122 branch from the other side portion 121b of the fin main portion 121, and extend away from each other toward the other side portion 121b from the one side portion 121a. At the same time, at least a part of the rising portion rises from the pedestal portion 110a.

  The heat sink 100a includes a pedestal portion 110a in which at least a portion facing the light emitting portion 210 from the fin disposition surface 112 protrudes in a columnar shape. Since the portion facing the light emitting unit 210 is formed thick by the pedestal unit 110a, heat from the back surface of the light emitting unit 210 can be efficiently absorbed. In other words, in the case of the tube portion 113, the portion that stands as the side surface of the tube portion 113 is partially thick, whereas in the case of the pedestal shape, the entire pedestal shape is thick, so the pedestal shape is a tube. Heat can be absorbed more uniformly than the cylindrical portion 113. Further, the pedestal portion 110a is provided with at least a part of the fin branch portion 122 as well as the fin main portion of the fin portion 120 in a plan view. Thus, by providing the fin portion 120, the number of places where the pedestal portion 110a and the fin portion 120 are connected can be increased, and the heat absorbed by the pedestal portion 110a can be efficiently transmitted to the fin portion 120, and the heat dissipation efficiency is improved. can do.

  As shown in FIG. 24, the heat sink 100 a is provided so that the fin branch portions 122 are separated from each other toward the outside from the center side. That is, since the fin branching portion 122 is provided so as to project obliquely, the distance L2 between the adjacent fin portions 120 can be secured while securing the length of L1 in the drawing, It is possible to make it difficult to trap heat and improve heat dissipation. If the fin fin branching portion 122 is provided so as to be perpendicular to the fin main portion, the distance L1 is shortened or the distance L2 is shortened. When the distance L1 is shortened, it is difficult for heat to be trapped in the fin branch portion 122, and when the distance L2 is shortened, heat is not easily trapped between the adjacent fin portions 120.

  FIG. 25 shows an example of the relationship between aluminum purity and heat dissipation due to differences in the heat sink molding method. As shown in FIG. 25, the heat dissipation can be improved by molding the heat sink by press working.

  In the heat sink 100a, the pedestal portion 110a and the base portion 110 and the plurality of fin portions 120 are integrally formed by forging. Also in the heat sink 100, the base portion 110 and the plurality of fin portions 120 are integrally formed by forging. Further, in the heat sink 100, the base portion 110 and the fin portion 120 are integrally formed of a material containing aluminum. Similarly, in the heat sink 100a, the pedestal portion 110a and the base portion 110 and the plurality of fin portions 120 are integrally formed of a material containing aluminum.

  The shape of the cylindrical portion 113 of the heat sink may be a cylindrical shape or a cylindrical shape having a polygonal cross section. Moreover, the shape which does not form a cylinder part may be sufficient.

  DESCRIPTION OF SYMBOLS 1 Lighting apparatus, 10 Lighting fixture, 20 Power supply device, 21 Lighting circuit board, 22 Terminal block, 22a Power supply terminal block, 22b Dimming terminal block, 23 Case main-body part, 23a Main body bottom part, 23aa 1st board part, 23ab 1st 2 plate parts, 23b body side part, 23c arm part, 24 case lid part, 24a lid bottom face part, 24b lid side part, 24c inclined part, 25 case, 31 electric wire, 32 gripping space, 33 virtual radius, 34 end part, 39 Axis of rotation, 100 heat sink, 100a heat sink, 110a pedestal, 110 base, 111 light source mounting surface, 112 fin mounting surface, 113 cylindrical portion, 120 fin portion, 120a rising direction, 121 fin main portion, 121a, 121b side portion, 122 fin branch portion, 122a inner surface of the branch portion, 123 end fin, 24 end fins, 125 bent portions, 125a first bent portions, 125b second bent portions, 126a first branch locations, 126b second branch locations, 130 power supply holding portions, 131 holding holes, 140 cord holding portions , 150 Electric wire cover part, 151 Power supply control part, 200 Light source part, 210 Light emitting part, 211 Light emitting element, 212 Substrate, 220 socket part, 221 Socket front part, 222 Socket rear part, 223 Clip, 230 cover part, 231 cover body Part, 232 cover opening part, 233 inner wall part, 234 outer wall part, 235 hook part, 235a projection part, 236 claw part, 237 frame receiving part, 238 light distribution control part, 300, 300A frame part, 310 collar part, 320 rise Part, 350 1st hole, 351 1st hole formation part, 360 2nd hole, 361 2nd hole formation part, 370 inclination part, 371 opening part, 400 attachment spring, 401 wire antenna, 402 wireless board, 500 to-be-attached part, 501 attachment hole, 502 horizontal direction.

Claims (8)

A base part to which a light source part is attached;
A plurality of fin portions arranged so that the base portion is positioned between the light source portion, and
Each fin part is equipped with
A fin main portion having a plate shape rising from the base portion and having one side portion along the rising direction and the other side portion along the rising direction,
A heat sink comprising: a plurality of fin branch portions branched from the other side portion of the fin main portion and extending away from each other toward the other side portion from the one side portion. A base part to which a light source part is attached;
A base portion protruding from the base portion at a position facing the light source portion with the base portion interposed therebetween;
A plurality of fin portions;
With
Each fin is
A heat sink in which a part of the rising part rises from the pedestal part and the remaining part of the rising part rises from the base part. Each fin is
A fin main portion having a plate-like shape rising from the pedestal portion and one side portion along the rising direction, and the other side portion along the rising direction,
A plurality of branches branching from the other side of the fin main portion and extending away from the one side toward the other side, and at least a part of the rising portion rises from the pedestal The heat sink of Claim 2 which has a fin branch part. The heat sink further comprises:
The heat sink according to claim 1, further comprising a plurality of end fins that branch from the end of the fin branching portion at an end in a direction in which at least one of the fin branching portions extends. The heat sink is
A power supply device for supplying power to the light source unit is attached,
The light source unit is
The temperature T with respect to the distance L with respect to the power supply apparatus that is supplying power is represented by the function f of T = f (L), and decreases linearly as the distance L increases and shifts to a saturated state. Transition to the transition range to reach the saturation state through the transition range,
The power supply device
The heat sink according to any one of claims 1 to 4, wherein the heat sink is attached to the heat sink at a position L in the transition range.   The heat sink according to any one of claims 1 to 5, wherein the base portion and the plurality of fin portions are integrally formed by forging.   The heat sink according to any one of claims 1 to 6, wherein the base portion and the fin portion are integrally formed of a material containing aluminum. A heat sink according to any one of claims 1 to 7,
A light source attached to the heat sink;
A power supply device for supplying power to the light source unit;
A lighting device comprising:

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