JP5600781B2 - Electrical equipment - Google Patents

Description

  The present invention relates to an electric device that radiates heat generated by a load such as an LED.

  2. Description of the Related Art In an electrical apparatus having a load that generates heat, such as an LED, a structure that radiates heat generated in the load into the air using a heat dissipation structure such as a heat dissipation fin is known.

JP 2008-186776 A JP 2008-98020 A Registered Utility Model No. 3148247 International Publication No. 2009/0444716 Japanese Patent Application No. 2008-153602 (Japanese Patent Laid-Open No. 2009-301810)

Even if the heat generated in the load is radiated by the heat dissipation structure as described above, the conduction heat is transmitted to the power supply circuit connected to the load circuit and the terminal block connected to the power supply circuit.
Increasing the distance between the power supply circuit and the load circuit can reduce the heat transferred to the power supply circuit, but increases the size of the entire electrical device.
The present invention has been made to solve the above-described problems, for example, and aims to reduce heat transmitted to a power supply circuit and the like and to reduce the size of an electric device.

  An electrical device according to the present invention is produced by the load circuit in contact with the main body having a heat generating load circuit, a power supply having a power circuit for supplying power to the load circuit, and the main body. Dissipates heat to form a space for housing the power supply unit, and covers the main body unit with the heat dissipation unit having an intake port through which air flowing between the power supply unit flows and engages with the intake port And a cover portion having a convex portion.

  According to the electric device of the present invention, since the heat radiating portion surrounds the power supply unit, the entire electric device can be reduced in size and heat transmitted from the main body unit to the power supply unit can be suppressed.

FIG. 3 is a perspective view illustrating an appearance of the lighting fixture 100 according to Embodiment 1. FIG. 3 is a side view showing the appearance of lighting apparatus 100 according to Embodiment 1. FIG. 3 is an exploded perspective view showing a configuration of main body 110 in the first embodiment. FIG. 3 is an exploded perspective view illustrating a configuration of the lighting fixture 100 according to Embodiment 1. FIG. 3 is a side cross-sectional view showing the lighting apparatus 100 according to Embodiment 1. FIG. 6 is an exploded perspective view illustrating a configuration of a lighting fixture 100 according to Embodiment 2. FIG. 6 is an exploded perspective view illustrating a configuration of a lighting fixture 100 according to Embodiment 2. FIG. 10 is an exploded perspective view illustrating a configuration of lighting apparatus 100 according to Embodiment 3. FIG. 10 is an exploded perspective view showing a configuration of a cover part 220 in the third embodiment. FIG. 6 is an exploded perspective view showing a configuration of main body heat radiation power supply unit 210 in the third embodiment. FIG. 9 is a schematic diagram showing a procedure for assembling a main body heat radiation power source unit 210 in a third embodiment. FIG. 9 is a schematic diagram showing a procedure for assembling a main body heat radiation power source unit 210 in a third embodiment. FIG. 10 is a schematic diagram illustrating a procedure for assembling the lighting fixture 100 according to Embodiment 3. FIG. 10 is a schematic diagram showing an air flow of lighting apparatus 100 according to Embodiment 3. FIG. 10 is a schematic diagram showing an air flow of lighting apparatus 100 according to Embodiment 3. FIG. 10 is a schematic diagram showing an air flow of lighting apparatus 100 according to Embodiment 3.

Embodiment 1 FIG.
The first embodiment will be described with reference to FIGS.

FIG. 1 is a perspective view showing the external appearance of a lighting fixture 100 in this embodiment.
The luminaire 100 (electric device) is downlight type illumination that is used by being embedded in, for example, a ceiling. The luminaire 100 is generally cylindrical. The luminaire 100 includes a main body part 110, a frame part 120, a heat radiating part 130, a power supply part 140, and a holding part 150.

The main body 110 has a load circuit including one or more LEDs (light sources) and wiring for supplying power to the LEDs.
The frame part 120 has a shape surrounding the main body part 110.
The heat radiating unit 130 (heat sink) radiates heat generated by lighting the LED.
The power supply unit 140 includes a power supply circuit that converts power supplied from a commercial power supply, a battery, or the like into power applied to the load circuit of the main body 110. The LED is turned on in response to the supply of power converted by the power supply circuit.
The holding unit 150 holds the power supply unit 140.

FIG. 2 is a side view showing the external appearance of the lighting fixture 100 in this embodiment.
The heat radiating part 130 is made of a material having high thermal conductivity such as aluminum. The heat dissipating part 130 is in contact with the frame part 120 and the main body part 110 surrounded by the frame part 120, absorbs heat generated by the LED by heat conduction, and dissipates it into the air. The heat radiating part 130 has a shape surrounding the power supply part 140 from the left and right.
The power supply unit 140 is sealed to prevent dust from entering the inside.
The holding unit 150 holds the power supply unit 140 so that the power supply unit 140 does not come into contact with the heat dissipation unit 130, the main body unit 110, or the frame unit 120. This prevents heat from being transferred from the heat radiating part 130 or the main body part 110 to the power supply part 140 by heat conduction. The holding part 150 and the heat radiating part 130 are screwed. The holding part 150 is in contact with the heat radiating part 130 at the screwing part. For this reason, heat is transmitted from the heat radiating unit 130 to the holding unit 150 by heat conduction directly or via a screw, and the heat is also transmitted to the power supply unit 140 by heat conduction. In order to reduce the heat transmitted to the power supply unit 140 as much as possible, the contact portion between the holding portion 150 and the heat radiating portion 130 is provided as far as possible from the contact portion between the main body portion 110 and the heat radiating portion 130. In this example, the contact portion between the main body part 110 and the heat radiating part 130 is the lower end of the heat radiating part 130. A contact portion between the holding unit 150 and the heat radiating unit 130 is an upper end of the heat radiating unit 130. The distance between the contact part between the main body part 110 and the heat radiation part 130 and the contact part between the holding part 150 and the heat radiation part 130 is equal to the height of the heat radiation part 130 and longer than the height of the power supply part 140. In addition, the holding unit 150 is desirably formed of a material having a lower thermal conductivity than the heat radiating unit 130 or the like.

FIG. 3 is an exploded perspective view showing the configuration of the main body 110 in this embodiment.
The main body 110 includes a load substrate 111, a reflecting plate 112, and a transparent plate 115.
The load substrate 111 (mounting substrate) has a substantially thin disk shape. The load substrate 111 has LEDs and other load circuits mounted on the lower surface.
The reflecting plate 112 has a short cylindrical shape and covers the lower side of the load substrate 111. The reflector 112 has a reflector 113 on the bottom surface. The reflecting mirror 113 is provided at a position corresponding to the LED on the load substrate 111. The reflecting mirror 113 has a mortar shape with no bottom, and reflects light emitted from the LED to control light distribution.
The transparent plate 115 has a disk shape that is substantially the same size as the bottom surface of the reflecting plate 112 and is made of a transparent material such as an acrylic plate. The transparent plate 115 protects the LED and the load substrate 111 from dust and the like by covering the reflecting mirror 113.

FIG. 4 is an exploded perspective view showing the configuration of the lighting fixture 100 in this embodiment.
The frame part 120 has a flange part 121 and a reflection part 122. The heat dissipating part 130 includes a disk part 131 and heat dissipating fins 132. The power supply unit 140 includes a power supply case 141 and a power supply board 146. The holding unit 150 includes a lid 151 and screws 156 and 157.

The reflecting part 122 has a cylindrical shape on the outside and a mortar shape without a bottom on the inside. The inside of the reflection part 122 reflects light, and the light leaked in the horizontal direction out of the light emitted from the LED is reflected downward to reduce useless light.
The flange part 121 is located at the lower end of the reflecting part 122 and has a collar shape. The flange portion 121 is a portion that protrudes below the ceiling surface when the lighting fixture 100 is embedded in a ceiling or the like.

The disk part 131 has a disk shape having substantially the same diameter as the outer diameter of the reflection part 122. The lower surface of the disc part 131 is substantially flat. The upper surface of the load substrate 111 is also substantially flat. The load substrate 111 is fixed in close contact with the disk portion 131 using, for example, an adhesive having high thermal conductivity. Thereby, the contact area of the disc part 131 and the load board | substrate 111 becomes large, and much heat is transmitted from the load board | substrate 111 to the disc part 131. FIG.
The frame portion 120 is formed of a material having high thermal conductivity such as aluminum as in the case of the heat radiating portion 130, and the upper surface of the reflecting portion 122 is placed below the heat radiating portion 130 with an adhesive having high thermal conductivity. If the structure is fixed to this surface, the heat transmitted from the load substrate 111 to the heat radiating part 130 is transmitted to the frame part 120 and radiated from the flange part 121 and the like, which is preferable because the heat radiation efficiency is increased.

The radiating fins 132 have, for example, a shape in which a large number of plates are arranged so that the contact area between the radiating unit 130 and the air is increased. The plates constituting the heat radiating fins 132 are roughly divided into two groups on the left and right sides, and a space for the power supply unit 140 is formed between them. The orientation of the plates constituting the radiating fins 132 is perpendicular to the longitudinal direction of the power supply unit 140. Thereby, since the fluidity | liquidity of the air around the power supply part 140 becomes high, the heat | fever transmitted to the power supply part 140 via the air warmed by the thermal radiation from the thermal radiation part 130 can be suppressed.
A screw hole 133 to be screwed with the screw 156 is provided at the upper ends of the four plates located at the end of the plates constituting the radiation fins 132.

The power supply substrate 146 is a substrate on which a power supply circuit (not shown in the figure) formed by electronic components or the like is mounted.
The power supply case 141 has a hollow, substantially rectangular parallelepiped shape whose upper surface is open, and surrounds the power supply substrate 146. The power supply case 141 blocks the air heated by the heat radiating unit 130, thereby suppressing heat transmitted to the power supply substrate 146.
At the upper end of the power supply case 141, a tongue-like portion having a screw hole 142 that is screwed into the screw 157 is provided.

The lid 151 has a substantially rectangular plate shape and is approximately the same size as the opening of the power supply case 141. The lid 151 is provided with a screw hole 153 through which the screw 157 is passed. Further, at the four corners of the lid 151, tongue-shaped portions having screw holes 152 through which the screws 156 are passed are provided.
The screw 157 passes through the screw hole 153 and is screwed with the screw hole 142 to fix the lid 151 to the power supply unit 140. The lid 151 closes the opening of the power supply case 141 to prevent dust and the like from entering the power supply case 141.
The screw 156 passes through the screw hole 152 and is screwed into the screw hole 133 to fix the lid 151 to the heat radiating unit 130. Thereby, the power supply part 140 is hold | maintained in the position which does not touch the thermal radiation part 130 or the main-body part 110. FIG.

  FIG. 5 is a cross-sectional side view showing the lighting apparatus 100 in this embodiment.

The heat generated in the LED is transmitted to the heat radiating unit 130 via the load substrate 111.
The heat transmitted to the heat radiating part 130 is radiated into the air directly from the heat radiating part 130 or via the frame part 120.
Part of the heat transmitted to the heat radiating unit 130 is transmitted to the power supply unit 140 via the holding unit 150. However, since the contact portion between the holding portion 150 and the heat radiating portion 130 is greatly separated from the contact portion between the heat radiating portion 130 and the main body portion 110, it is transmitted from the heat radiating portion 130 to the power supply portion 140 via the holding portion 150. The heat is negligible.
In addition, there is heat transmitted to the power supply unit 140 from the air heated by the heat radiation from the heat radiation unit 130. However, since the fluidity of the air around the power supply unit 140 is high, the air heated by the heat dissipation from the heat dissipation unit 130 does not stay around the power supply unit 140, and the power is supplied from the air heated by the heat dissipation from the heat dissipation unit 130. Very little heat is transferred to section 140.

  Thus, since the lighting fixture 100 (electrical equipment) in this embodiment has a shape in which the heat dissipation portion 130 surrounds the power supply portion 140, the entire lighting fixture 100 can be reduced in size. Nevertheless, since the heat transmitted from the main body 110 to the power supply 140 is very small, the power supply circuit can be configured with parts having low heat resistance, and the manufacturing cost of the lighting apparatus 100 can be suppressed.

In addition, in order to further reduce the heat transmitted to the power supply unit 140 from the air heated by the heat dissipation from the heat dissipation unit 130, a heat insulating layer is formed by a heat insulating material or the like in the space between the heat dissipation unit 130 and the power supply unit 140. It is good also as composition to do.
Further, a heat dissipating fin may be provided on the holding unit 150 so as to dissipate heat transmitted from the heat dissipating unit 130 or heat generated by the power supply unit 140.

  In addition, although the lighting fixture which has LED as a light source was demonstrated here as an example, it is applicable also to the lighting fixture which has other light sources, such as a halogen lamp. Moreover, it is applicable not only to lighting equipment but also to other electric devices having a load that generates heat.

Embodiment 2. FIG.
The second embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 1, the same code | symbol is attached | subjected and description is abbreviate | omitted.

6 and 7 are exploded perspective views showing the configuration of the lighting apparatus 100 according to this embodiment.
The luminaire 100 includes a leaf spring 160 and terminal blocks 170 and 180 in addition to the configuration described in the first embodiment.

The leaf spring 160 is a configuration for detachably fixing the luminaire 100 in a hole provided in the ceiling or the like.
The terminal block 170 connects wiring from a commercial power source or the like, and inputs power from the commercial power source or the like. The terminal block 170 and the power supply circuit in the power supply unit 140 are connected by a wiring 147.
Further, the power supply circuit and the load circuit in the main body 110 are connected by a wiring 148 and a connector 149. The power converted by the power supply circuit is supplied to the load circuit via the wiring 148 and the connector 149.
The power supply case 141 has holes for leading out the wiring 147 and the wiring 148. The sealing material 143 seals the hole so that air heated by heat radiation from the heat radiating unit 130 does not enter the power supply case 141 from this hole. The sealing material 143 is, for example, resin or rubber packing. Note that the sealing material 143 is not provided and the hole is not necessarily sealed.
Of the radiating fins 132, the height of the portion of the radiating fin 132 that contacts the terminal blocks 170 and 180 is low. Thereby, not only the terminal blocks 170 and 180 do not touch the heat radiation fins 132 but also the wiring from the commercial power supply can be connected to the terminal block 170 without touching the heat radiation fins 132.

  Even with this configuration, the same effects as those of the first embodiment can be obtained.

Embodiment 3 FIG.
A third embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 1 and Embodiment 2, the same code | symbol is attached | subjected and description is abbreviate | omitted.
The appearance of the lighting fixture 100 in this embodiment is the same as that of the second embodiment.

FIG. 8 is an exploded perspective view showing the configuration of the lighting fixture 100 in this embodiment.
The luminaire 100 includes a main body heat radiation power supply unit 210, a cover unit 220, and four screws 281. The main body heat radiation power supply unit 210 is configured by combining the main body unit 110, the heat radiation unit 130, the power supply unit unit 230, and the like. The cover part 220 is configured by combining the frame part 120, the leaf spring 160, the transparent plate 115, and the like. The screw 281 fixes the main body heat radiation power source unit 210 and the cover unit 220.

FIG. 9 is an exploded perspective view showing the configuration of the cover part 220 in this embodiment.
The cover part 220 includes a frame part 120, two leaf springs 160, and a transparent plate 115.
The leaf spring 160 has a T-shaped leaf spring engaging portion 161 at one end. The frame portion 120 has a frame engaging portion 123 having a shape that engages with the leaf spring engaging portion 161 at a position where the leaf spring 160 is attached. The leaf spring 160 is fixed to the frame portion 120 when the leaf spring engaging portion 161 and the frame engaging portion 123 are engaged. Further, the transparent plate 115 is fixed by being sandwiched between the main body 110 and the frame 120 by fixing the main body heat radiation power source 210 and the cover 220 with screws 281.

FIG. 10 is an exploded perspective view showing the configuration of the main body heat radiation power supply unit 210 in this embodiment.
The main body heat radiation power supply unit 210 includes a power supply unit unit 230, a heat radiation unit 130, a heat radiation insulating rubber 240, a load substrate 111, a reflector 112, and four screws 213.

The power unit 230 includes a power unit 140, a terminal block 180, and a holding unit 150.
The power supply unit 140 has a built-in power supply circuit. The power supply unit 140 includes a sealing material 143, wiring 148, and a connector 149. By connecting the connector 149 to the load board 111, the power generated by the power supply circuit is supplied to the load board 111 via the wiring 148.

The heat radiating part 130 includes a disk part 131, a plurality of heat radiating fins 132, and two air inlets 136.
The disc part 131 has two projecting parts 135, a wiring notch part 137, and eight screw holes 211 and 291. The protrusion 135 is a protrusion for determining the positions of the heat radiation insulating rubber 240 and the reflection plate 112 when the main body heat radiation power source 210 is assembled. The wiring notch 137 is a notch for allowing the wiring 148 to pass therethrough. The screw hole 211 is a screw hole for fixing the reflecting plate 112 to the heat radiating unit 130. The screw hole 291 is a screw hole for fixing the main body heat radiation power supply unit 210 and the cover unit 220.
The intake port 136 is an opening provided at the lower corner of the power unit unit 230 at a position corresponding to the longitudinal direction. The intake port 136 is an intake port for taking in air for cooling the heat radiation fins 132. One of the two air inlets 136 is connected to the wiring cutout 137.

  The heat radiation insulating rubber 240 has a thin plate shape, has high thermal conductivity, and is electrically insulated. The heat radiation insulating rubber 240 is sandwiched between the load substrate 111 and the heat radiation portion 130 to eliminate a gap. Thereby, the heat generated in the load substrate 111 is efficiently transmitted to the heat radiating unit 130. The heat radiation insulating rubber 240 has two through holes 241. The through hole 241 is provided at a position corresponding to the protruding portion 135. When assembling the main body heat-dissipating power supply unit 210, the position of the heat-dissipating insulating rubber 240 can be easily determined by aligning the through hole 241 with the protrusion 135.

The load board 111 has a plurality of LEDs and connectors 119. The connector 119 inputs power generated by the power supply circuit of the power supply unit 140 by connecting to the connector 149. The LED is turned on by the power input from the connector 119 and generates heat.
The reflecting plate 112 has a plurality of reflecting mirrors 113, four screw holes 212, and two engaging recesses 216. The reflecting mirror 113 is provided at a position corresponding to the LED of the load substrate 111, reflects light emitted from the LED, and controls light distribution. The screw hole 212 is a screw hole for fixing the reflecting plate 112 to the heat radiating unit 130. The engaging recess 216 is provided at a position corresponding to the protrusion 135. When assembling the main body heat radiation power source 210, the position of the reflector 112 can be easily determined by aligning the engaging recess 216 with the protrusion 135.
The screw 213 fixes the reflecting plate 112 and the heat dissipation part 130. The screws 213 fix the reflecting plate 112 and the heat radiating portion 130, whereby the heat radiating insulating rubber 240 and the load substrate 111 are sandwiched and fixed between the reflecting plate 112 and the heat radiating portion 130.

FIG. 11 is a schematic diagram showing a procedure for assembling the main body heat radiation power supply unit 210 in this embodiment.
First, with the disk portion 131 side of the heat radiating portion 130 facing up, the wiring 148 of the power supply unit portion 230 is passed from below through the air inlet 136 connected to the wiring cutout portion 137, and the connector 149 is exposed upward (wiring insertion) Process).
On the disc part 131, the heat radiation insulating rubber 240 is installed (heat radiation insulation rubber installation process). At this time, the position of the heat radiation insulating rubber 240 is determined by aligning the through hole 241 with the protrusion 135.
The connector 149 is connected to the connector 119 of the load board 111 (connector connection process). In order to facilitate the work in the connector connection step, the wiring 148 has a certain amount of margin.
The load substrate 111 is installed on the heat radiation insulating rubber 240 (load substrate installation step).
The reflecting plate 112 is placed on the heat insulating rubber 240 and the load substrate 111 (reflecting plate installing step). At this time, the position of the reflecting plate 112 is determined by aligning the engaging recess 216 with the protrusion 135.
The screw 213 is passed through the screw hole 212 of the reflecting plate 112 and screwed into the screw hole 211 of the heat radiating unit 130, thereby fixing the reflecting plate 112 (and the load substrate 111 and the heat radiating insulating rubber 240) to the heat radiating unit 130 ( Reflector fixing step).
Finally, the power supply unit 230 is housed and fixed in a space surrounded by the radiation fins 132 (power supply unit installation process / power supply unit fixing process).

  As described above, the wiring 148 has a certain margin in consideration of workability in the connector connection process. The length of the wiring 148 is preferably slightly longer than the length of the power supply unit 230 in the longitudinal direction. As a result, when the power supply unit 230 is housed in the space surrounded by the heat radiation fins 132, the wiring 148 can be accommodated between the power supply unit 230 and the disk part 131 without any excess. Will be better.

FIG. 12 is a schematic diagram showing a procedure for assembling the main body heat radiation power supply unit 210 in this embodiment.
Tapered portions 215 are provided inside the heat radiating fins 132, and the distance between the opposing heat radiating fins 132 becomes narrower toward the side closer to the disk portion 131.
In the power supply unit installation process, when the power supply unit portion 230 is housed in the space surrounded by the radiation fins 132, the corners (contact portion 214) of the power supply portion 140 abut against the taper portion 215. Then, the light is guided to the correct position in the center of the space surrounded by the radiation fins 132. Thereby, the position of the power supply unit 230 can be easily determined.

  A configuration in which a wing-like projection is provided as a contact portion on the side of the power supply unit 140 and the wing-like projection contacts between the parallel radiating fins 132 to determine the position of the power supply unit 230 in the longitudinal direction. Also good. Thereby, since the position of the power supply unit 230 is determined in both the vertical and horizontal directions, the work efficiency in the power supply unit installation process is further increased.

FIG. 13 is a schematic diagram showing a procedure for assembling the lighting fixture 100 in this embodiment.
This figure is a front view and a right side sectional view. Note that the leaf spring 160 is not shown in the front view so that the main part can be easily seen.

The frame part 120 has two convex parts 124. The convex portion 124 is provided at a position corresponding to the intake port 136. When the convex portion 124 is engaged with the air inlet 136, the positional relationship between the main body heat radiation power source section 210 and the cover section 220 can be easily determined.
That is, by engaging the convex portion 124 and the intake port 136, the positions of the main body heat radiation power supply unit 210 and the cover unit 220 are determined, the screws 281 are passed through the screw holes 291 of the heat radiation unit 130, and The main body heat radiation power supply unit 210 and the cover unit 220 are fixed by being screwed into the screw holes.

The height of the convex portion 124 is approximately the same as the thickness of the disc portion 131. Thereby, air can be taken in from the intake port 136 without the convex part 124 blocking the intake port 136.
Further, since the wiring cutout portion 137 is connected to the intake port 136, the wiring 148 is exposed as it is, but the convex portion 124 engages with the intake port 136 to cover the wiring 148.

  Each component of the lighting fixture 100 has the above-described structure, and assembling the lighting fixture 100 as described above increases the efficiency of the assembly work.

14-16 is a schematic diagram which shows the flow of the air of the lighting fixture 100 in this Embodiment.
The air taken in from the intake port 136 flows into the gap between the power supply unit part 230 and the disk part 131. Since the heat generated by the LED is transferred to the disk portion 131, the heat is transferred to the air flowing into the gap.
The air that has passed between the power supply unit 230 and the disk portion 131 passes to the side of the power supply unit 230, rises while passing between the radiating fins 132, and is further transferred from the radiating fins 132 to the outside. To be released.

  As described above, the air flowing from the air inlet 136 is transferred by the disk portion 131 and the heat radiating fins 132 and is released to the outside, thereby efficiently radiating the heat generated by the LEDs. it can.

  Thus, by efficiently dissipating the heat generated by the LED, the lifetime of the LED can be extended, and the luminous efficiency of the LED can be increased.

In the above-described embodiment, an example of the following electrical device has been described.
A main body having a load circuit that generates heat; a power source having a power supply circuit that supplies power to the load circuit; and contacting the main body to dissipate heat generated by the load circuit; An electric apparatus comprising: a heat dissipating part that surrounds the power source part; and a holding part that retains the power supply part in a position not in contact with the main body part and the heat dissipating part.

  The electric device according to claim 1, wherein the holding portion is in contact with the heat radiating portion at a position separated by a predetermined distance or more from a position where the heat radiating portion and the main body portion are in contact with each other.

  A main body having a load circuit that generates heat; a power source having a power supply circuit that supplies power to the load circuit; and contacting the main body to dissipate heat generated by the load circuit; An electric apparatus comprising: a heat dissipating part having a shape surrounding the heat-dissipating part, wherein the heat dissipating part has an air inlet into which air flowing between the power supply part flows.

  The electrical apparatus according to claim 1, wherein the heat dissipating unit includes an air inlet through which air flowing between the power source unit and the heat sink flows.

  The electric device has a cover portion that covers the main body portion, and the cover portion has a convex portion that engages with the air inlet and determines a mounting position of the cover portion.

  The heat radiating portion has a tapered portion surrounding the power supply portion, and the tapered portion abuts on the power supply portion to determine an attachment position of the power supply portion.

  The heat dissipating part has a plurality of plate-like heat dissipating fins arranged substantially in parallel, and the power supply part has an abutting part that abuts between the plurality of heat dissipating fins to determine the mounting position of the power supply part. Electrical equipment characterized by

  The power supply unit includes a power supply line for supplying power to the main body unit, the main body unit includes a connector unit for connecting the power supply line, and the power supply line is connected between the heat dissipation unit and the power supply unit. An electrical device having a length accommodated in between and connected to the connector portion through the intake port.

  The electrical device is a lighting fixture, and the load circuit includes a light source.

  The load circuit includes a light emitting diode as the light source.

  DESCRIPTION OF SYMBOLS 100 Lighting fixture, 110 Main-body part, 111 Load board, 112 Reflector plate, 113 Reflector, 115 Transparent plate, 120 Frame part, 121 Flange part, 122 Reflector part, 123 Frame engaging part, 124 Convex part, 130 Heat radiating part, 131 Disc part, 132 Radiation fin, 133, 142, 152, 153, 211, 212, 291 Screw hole, 135 Protrusion part, 136 Air inlet, 137 Wiring notch part, 140 Power supply part, 141 Power supply case, 143 Sealing material 146 Power supply board, 147, 148 wiring, 119, 149 connector, 150 holding part, 151 lid, 156, 157, 213, 281 screw, 160 leaf spring, 161 leaf spring engaging part, 170, 180 terminal block, 210 body Heat dissipation power source, 214 abutting part, 215 taper part, 216 engaging recess, 220 cover part , 230 Power supply unit, 240 heat radiation insulating rubber, 241 through hole.

Claims (6)

A main body having a load circuit for generating heat;
A power supply unit having a power supply circuit for supplying power to the load circuit;
A heat dissipating part that contacts the main body part to dissipate heat generated by the load circuit, forms a space for housing the power supply part, and has an air inlet into which air flowing between the power supply part flows. ,
A cover portion that covers the main body portion and has a convex portion that engages with the air inlet;
The heat dissipating part has a taper part surrounding the power supply part,
The taper portion is in contact with the power supply portion and determines an attachment position of the power supply portion . The heat dissipating part has a plurality of plate-like heat dissipating fins arranged in parallel,
The electric device according to claim 1 , wherein the power supply unit includes an abutting portion that abuts between the plurality of radiating fins and determines a mounting position of the power supply unit. The power supply unit has a power supply line for supplying power to the main body unit,
The main body has a connector for connecting the power line,
The said power supply line has the length accommodated between the said heat radiating part and the said power supply part, It connects to the said connector part through the said inlet port, The Claim 1 or 2 characterized by the above-mentioned. Electrical equipment.   A main body having a load circuit for generating heat;
  A power supply unit having a power supply circuit for supplying power to the load circuit;
  A heat dissipating part that contacts the main body part to dissipate heat generated by the load circuit, forms a space for housing the power supply part, and has an air inlet into which air flowing between the power supply part flows. ,
  A cover portion that covers the main body portion and has a convex portion that engages with the air inlet;
With
  The heat dissipating part has a plurality of plate-like heat dissipating fins arranged in parallel,
  The electric power device includes an abutting portion that abuts between the plurality of heat radiating fins to determine a mounting position of the power source portion.   The power supply unit has a power supply line for supplying power to the main body unit,
  The main body has a connector for connecting the power line,
  5. The electric power according to claim 4, wherein the power line has a length stored between the heat radiating part and the power source part, and is connected to the connector part through the air inlet. machine.   A main body having a load circuit for generating heat;
  A power supply unit having a power supply circuit for supplying power to the load circuit;
  A heat dissipating part that contacts the main body part to dissipate heat generated by the load circuit, forms a space for housing the power supply part, and has an air inlet into which air flowing between the power supply part flows. ,
  A cover portion that covers the main body portion and has a convex portion that engages with the air inlet;
With
  The power supply unit has a power supply line for supplying power to the main body unit,
  The main body has a connector for connecting the power line,
  The electric device has a length accommodated between the heat radiating portion and the power supply portion, and is connected to the connector portion through the intake port.

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