JP2019192472A - Lighting device - Google Patents

Abstract

To provide a lighting device achieving high heat radiation performance.SOLUTION: A lighting device 1 includes: a light source part 2 including light emitting elements serving as light sources; and a heat radiation part 3 in which the light source part 2 is mounted on the front side. The heat radiation part 3 includes a heat pipe 39 and multiple fins 35 provided at the heat pipe 39.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an illuminating device including a heat radiating means.

An illuminating device provided with a heat dissipation means has been proposed (for example, Patent Documents 1 and 2).
The lighting device described in Patent Document 1 is described as follows: “The LED lighting device includes a housing 15 having a connection portion with a power supply unit, an LED substrate 13, and a translucent shade 14. The LED substrate 13 is a housing. The first LED element and a second LED element having a wavelength different from that of the first LED element are mounted on the outgoing light side of the body 15. The translucent shade 14 is a casing 15. And a scattering portion 18 that scatters the light emitted from the LED element, and a heat sink 15a is formed on the housing 15 to dissipate heat between the LED substrate 13 and the housing 15. Insulating sheet 16 is disposed ”.
The illuminating device described in Patent Document 2 includes a “substantially spherical light source unit in which a light source is incorporated, and an instrument body that rotatably holds the light source unit, and the instrument body emits light from the light source unit. In a lighting fixture provided with a pressing member that contacts and holds an end portion on the opposite side of the surface and positions and holds the light source unit, the light source unit includes at least one pair in a direction opposite to the light projecting side. Heat dissipation protrusions are erected, and these protrusions sandwich the pressing member from side to side and are spaced from the pressing member by an interval that can avoid interference with the pressing member accompanying the rotation of the light source unit. It is arranged at a spaced position, and a heat pipe is attached to the protrusion ”.

JP2015-018723A JP 2009-259551 A

In the illuminating device, heat dissipation is improved by providing a heat sink or attaching a heat pipe to the protrusion, but further improvement in heat dissipation is desired depending on the intended use.
An object of this invention is to provide the illuminating device which has high heat dissipation.

  An illuminating device according to the present invention includes a light source unit including a light emitting element as a light source, and a heat radiating unit on which the light source unit is mounted on the front side. And a fin.

  According to the said structure, since the several fin is provided in the heat pipe, the heat of a heat pipe can be thermally radiated efficiently.

(A) is the perspective view which looked at the illuminating device from the back side, (b) is the perspective view which looked at the illuminating device from the front side. It is a longitudinal cross-sectional view of an illuminating device. It is the perspective view which looked at the decomposition | disassembly state of an illuminating device from the front side. It is the perspective view which looked at the decomposition | disassembly state of an illuminating device from the back side. (A) is the cross-sectional view of a thermal radiation part, (b) is the figure which looked at the state which removed the fin from the heat pipe from the back side. (A) is the perspective view which looked at the thermal radiation part which concerns on 2nd Embodiment from the front side, (b) is the perspective view which looked at the thermal radiation part from the back side. (A) is a longitudinal cross-sectional view of the thermal radiation part which concerns on 2nd Embodiment, (b) is a cross-sectional view of a thermal radiation part. (A) is a side view of the thermal radiation part which concerns on 3rd Embodiment, (b) is a longitudinal cross-sectional view of a thermal radiation part. It is a figure which shows a test result.

<Overview>
An illumination device according to an aspect of an embodiment includes a light source unit including a light emitting element as a light source, and a heat radiating unit that mounts the light source unit on a front side. The heat radiating unit is provided on the heat pipe and the heat pipe. A plurality of fins.
In the lighting device according to another aspect of the embodiment, the plurality of fins are integrally formed with the heat pipe. As a result, heat is conducted directly from the heat pipe to the fins.
In the lighting device according to another aspect of the embodiment, the fin is made of a metal plate, and the plurality of fins are attached to the heat pipe. As a result, heat is conducted directly from the heat pipe to the fins.
In the lighting device according to another aspect of the embodiment, the inner surface of the heat pipe is a rough surface. Thereby, the heat exchange efficiency of the heat pipe can be improved.
In the lighting device according to another aspect of the embodiment, the plurality of fins are provided on the heat pipe along a direction in which an axis of the heat pipe extends. As a result, heat is conducted directly from the heat pipe to the fins.

<First Embodiment>
1. Outline The lighting device 1 according to the embodiment is a so-called downlight that is used in a state of being fitted to an opening of an installation surface such as a ceiling wall.
The illumination device 1 is a device that irradiates one side in a direction orthogonal to the installation surface. When the installation surface is a ceiling wall, the irradiation direction is downward. Here, the light emission direction is the front side, and the installation surface side is the back side.
As shown in FIGS. 3 and 4, the illumination device 1 includes a light source unit 2 including a light emitting element as a light source, and a heat radiating unit 3 that mounts the light source unit 2 on the front side. The heat of the light emitting element at the time of lighting is released from the heat radiating part 3.
The illumination device 1 includes a holder portion 4 that holds the light source portion 2 mounted on the heat radiating portion 3. The illumination device 1 includes a translucent cover portion 5 that covers the light source portion 2 from the front side. The illumination device 1 includes a reflection unit 6 that reflects light from the light source unit 2 downward. The illumination device 1 includes a frame portion 7 for attaching the translucent cover portion 5 and the reflection portion 6 to the holder portion 4.
Hereinafter, each part will be described.

2. Each part structure (1) Light source part It demonstrates using FIG.3 and FIG.4 mainly.
The light source unit 2 includes one or more LED elements as light sources, and the LED elements are mounted on the substrate 21. The LED element is covered with a translucent resin 23. For this reason, the LED element does not appear in FIG.

(2) Heat radiation part The heat radiation part 3 is provided with the mounting member 31, the cylindrical body 33, the some fin 35, and the cover member 37, as shown in FIGS. The mounting member 31, the cylindrical body 33, and the lid member 37 constitute a heat pipe 39 (see FIG. 2). That is, the heat radiating unit 3 includes the heat pipe 39 and the fins 35.

(2-1) The mounting member will be described mainly with reference to FIGS.
The mounting member 31 is made of a metal material. As the metal material, copper having good thermal conductivity is used. The mounting member 31 has a function of mounting the light source unit 2 and a function of closing the front side opening of the cylindrical portion 33 a of the cylindrical body 33.
The mounting member 31 has a plate-like portion 31a. The surface of the plate-like portion 31a is flat. The light source unit 2 is mounted at the center of a flat surface. The plate-like portion 31a here has a circular shape.
The mounting member 31 has a protruding portion 31b at the center of the back surface of the plate-like portion 31a. The protruding portion 31b protrudes on the back side. The protruding portion 31b is fitted to the opening end portion on the front side of the cylindrical body 33 through the packing. Thereby, the front side opening of the cylindrical body 33 is closed in an airtight manner.
The mounting member 31 has a back collar part 31c extending from the periphery of the plate-like part 31a to the back side. The back collar portion 31 c is fitted with the step portions 35 d on the front side of the plurality of fins 35 attached to the cylindrical body 33.
The mounting member 31 has a fixing portion 31 d for fixing to the cylindrical body 33 in the plate-like portion 31 a. Here, a screw 81 is used for fixing, and the fixing portion 31d is configured by a through hole.
The mounting member 31 has a fixing portion 31e for fixing the holder portion 4 to the heat dissipation portion 3 (mounting member 31) in the plate-like portion 31a. Here, a screw 82 is used for fixing, and the fixing portion 31e is constituted by a screw hole.

(2-2) Cylindrical body It demonstrates mainly using FIG.
The cylindrical body 33 is made of a metal material. The cylindrical body 33 has a cylindrical portion 33a. Here, the cylindrical portion 33a has a cylindrical shape. The cylindrical body 33 has a plurality of grooves 33b extending in the circumferential direction on the outer peripheral surface of the cylindrical portion 33a in the circumferential direction. Thus, for example, an extruded product of aluminum can be used as the cylindrical body 33. .
The groove 33b is constituted by a pair of convex portions 33c extending along the cylinder axis. That is, the gap between the pair of convex portions 33c is a groove 33b. A fin 35 described later is attached to the groove 33b.
The cylindrical body 33 is airtightly closed at the front side opening by the above-described mounting member 31 and the back side opening by the lid member 37, and hydraulic fluid (not shown) is inserted (enclosed) in the internal space. . That is, the tubular body 33, the mounting member 31, the lid member 37, and the hydraulic fluid constitute a heat pipe. As the hydraulic fluid, alternative fluorocarbons such as R134a, ethanol, acetone, water, etc. can be used.

The cylindrical body 33 has a fixing portion 33 d for fixing the mounting member 31. In addition, although the fixing | fixed part 33d is not shown in figure, in order to distinguish from another fixing | fixed part, the code | symbol "33d" is attached | subjected. The cylindrical body 33 has a fixing portion 33 e for fixing the lid member 37. Here, screws 81 and 83 are used to fix the mounting member 31 and the lid member 37, and screw grooves are used as the fixing portions 33d and 33e. The thread groove utilizes a “C” -shaped groove 33g extending in a “C” shape outwardly in the radial direction from two portions facing each other across the cylinder axis on the outer peripheral surface of the cylindrical portion 33a. . That is, the “C” -shaped groove 33g is provided in the front and back direction along the cylinder axis of the cylindrical portion 33a, and the fixing portion 33d (not shown) is configured at the front end of the “C” -shaped groove 33g and fixed. As shown in FIG. 5B, the portion 33e is configured at the back side end of the “C” -shaped groove 33g. A screw 81 is screwed into the fixing portion 33d, and a screw 83 is screwed into the fixing portion 33e.
A groove 33h extending in the cylinder axis direction is provided at the radial end of the “C” -shaped groove 33g. The groove 33h is for the fin 35 and is configured by a pair of convex portions 33j.

Part or all of the inner peripheral surface of the cylindrical portion 33a is a rough surface. The rough surface is formed by sandblasting or etching. Here, the roughness can be appropriately selected within a range where the calculated average roughness (Ra) is 15 to 20 [μm]. Thereby, the contact area of the working fluid in the heat pipe 39 and the inner peripheral surface of the cylindrical portion 33a is increased, and heat exchange with the working fluid is efficiently performed.
The cylindrical body 33 has an oxide film (not shown) on the inner peripheral surface of the cylindrical portion 33a. The oxide film is formed by an anodic oxidation method, and the inner peripheral surface of the cylindrical portion 33a is passive. Thereby, for example, when the cylindrical body 33 is made of aluminum and water is applied as the hydraulic fluid, corrosion of the cylindrical body 33 can be suppressed.

(2-3) Fin Description will be given mainly with reference to FIG.
The fin 35 uses a thin metal plate. There are a plurality of fins 35, and are provided at equal intervals in the circumferential direction with respect to the cylindrical body 33.
The fin 35 as an example is formed by bending one metal plate into a “V” shape. The fin 35 here is comprised from a pair of board part 35a, 35b and the bending part 35c which has connected board part 35a, 35b.
The fin 35 is attached to the tubular body 33 in a state where the bent portion 35 c is inserted into the groove 33 b of the tubular body 33. The fins 35 are fixed by caulking at least two locations of the front side end and the back side end of the groove 33b in which the fins 35 are inserted.
As the fin 35, a metal plate (for example, aluminum (including an aluminum alloy), copper, or the like) having a thickness of 0.3 to 0.7 [mm] is used. The fins 35 are provided so that the plate portions 35b, 35a of the other fins 35 adjacent in the circumferential direction and the plate portions 35a, 35b are substantially parallel to each other.

When viewed from the front and back directions, the fin 35 has a “V” shape as described above, but when viewed from the direction orthogonal to the cylinder axis of the cylindrical body 33, the plate portions 35a and 35b are in the front and back direction. It has a shape close to a long rectangular shape. The plate portions 35 a and 35 b have a front end and a back end corresponding to the short side, and have a stepped portion 35 d near the center of the cylindrical body 33 in the radial direction. The step portion 35d is configured by projecting the bent portion 35c side portion of the plate portions 35a and 35b outward in the longitudinal direction.
As shown in FIG. 2, the projecting portion constituting the stepped portion 35 d is located inside the back collar portion 31 c of the mounting member 31 on the front side, and located inside the front collar portion 37 c of the lid member 37 on the back side. To do. Accordingly, the movement of the plurality of thin fins 35 in the radial direction is restricted by the mounting member 31 and the lid member 37.

(2-4) Lid member The lid member will be described mainly with reference to FIGS.
The lid member 37 is made of a metal material. As the metal material, copper having good thermal conductivity is used. The lid member 37 mainly has a function of closing the back side opening of the tubular portion 33a of the tubular body 33.
The lid member 37 has a plate-like portion 37a. Here, the plate-like part 37a has a circular shape. As shown in FIG. 3, the lid member 37 has a cylindrical projecting portion 37b on the surface of the plate-like portion 37a. The cylindrical protruding portion 37b protrudes in a cylindrical shape on the front side. The cylindrical projecting portion 37b is fitted to the opening end portion on the back side of the cylindrical body 33 through the packing. Thereby, the back side opening of the cylindrical body 33 is airtightly closed.
The lid member 37 has a front flange portion 37c extending from the periphery to the front side in the plate-like portion 37a. The front collar portion 37 c is fitted with a step portion 35 d on the back side of the fin 35 attached to the cylindrical body 33.

The lid member 37 has a through hole 37d (see FIG. 3) at a portion located in the cylindrical projecting portion 37b and a cylindrical portion 37e (see FIG. 4) extending from the periphery of the through hole 37d to the back side. The through-hole 37d and the cylindrical part 37e constitute a suction port (suction path) when the inside of the cylindrical part 33a of the cylindrical body 33 is decompressed. The cylindrical portion 37e is crimped in an airtight manner during decompression in the cylindrical portion 33a.
The lid member 37 has a fixing portion 37 f for fixing to the cylindrical body 33. Here, a screw 83 is used for fixing, and the fixing portion 37f is constituted by a through hole.

(3) Holder Part Hereinafter, description will be given mainly using FIG. 3 and FIG.
The holder part 4 has a function of holding the light source part 2 mounted on the surface of the heat dissipation part 3 (mounting member 31). The holder part 4 is attached to the heat radiating part 3 and has a function of supporting the plurality of fins 35 of the heat radiating part 3.
The holder part 4 is constituted by a plate member 41. The plate member 41 has a plate-like portion 41a. The plate member 41 has an opening 41b in the plate-like portion 41a for exposing the translucent resin 22 of the light source unit 2 to the front side.

The plate member 41 has a fixing portion 41 c for fixing to the heat radiating portion 3 in the plate-like portion 41 a. Here, a screw 82 is used for fixing, and the fixing portion 41c is configured by a through hole. The screw 82 is screwed into the fixing portion (screw hole) 31e of the mounting member 31.
The plate member 41 has a support portion 41d that supports the plurality of fins 35 in the plate-like portion 41a. As shown in FIG. 5B, the support portion 41d includes a cylindrical portion 41e extending from the plate-like portion 41a to the back side, and a groove portion 41f provided at the back side end of the cylindrical portion 41e. The groove portion 41f is formed so as to be recessed in the front side. The groove portion 41 f corresponds to the pitch of the plate portions 35 a and 35 b of the fin 35. In addition, the groove width is large at the back side end of the groove portion 41f in order to guide the fin 35.

As shown in FIG. 3, the plate member 41 has a positioning portion 41h for the translucent cover portion 5 in the plate-like portion 41a. The positioning part 41h here is constituted by a cylindrical part fitted to the opening side end of the dome-shaped cover body 51.
The plate member 41 has a fixing portion 41 i for fixing the holder portion 4 to the frame portion 7 with the reflecting portion 6 in the plate-like portion 41 a. Here, a screw 84 is used for fixing, and the fixing portion 41i is formed by a through hole.
The plate member 41 is for preventing interference with the chipped portion 41j for arranging a fixture 45 for fixing a cable for supplying power to the light source unit 2 from a power supply device (not shown) and the plate spring body 73 of the frame unit 7. Are provided in the plate-like portion 41a.

(4) Translucent cover part The translucent cover part 5 is comprised by the cover body 51 which consists of translucent resin. The cover body 51 has a dome shape and performs optical processing on the light from the light source unit 2. Here, a diffusion lens 51a is formed on the front surface (outer surface), and a condenser lens 51b is formed on the back surface (inner surface).
The cover body 51 has an outer flange portion 51c that protrudes outward in the radial direction from the opening end. The cover body 51 is mounted on the holder part 4 side by holding the outer flange part 51 c between the holder part 4 and the reflection part 6.

(5) Reflection part The reflection part 6 is comprised by the reflector 61 which has the cylinder part 61a which makes the front side expansion cylindrical shape. The inner peripheral surface of the cylindrical portion 61a is a reflective surface 61b to which a white paint having a high reflectance is applied.
The reflector 61 is made of a resin material. The reflector 61 has an outer flange portion 61c that projects outward in the radial direction at the front side end of the cylindrical portion 61a. The outer flange portion 61 c is fitted into the stepped portion 71 c of the frame body 71 constituting the frame portion 7.
The reflector 61 has an engaging portion 61d extending in an “L” shape for engaging the inner flange portion 71d of the frame body 71 at the back side end portion of the cylindrical portion 61a.

(6) Frame part The frame part 7 is comprised from the frame body 71 which has the cylinder part 71a which has a substantially straight extended cylinder shape, and the leaf | plate spring body 73 for mounting | wearing the illuminating device 1 to the opening of an installation surface. Yes.
The frame body 71 has an outer flange portion 71b projecting radially outward from the front side end of the cylindrical portion 71a and a stepped portion 71c formed at the front side end portion of the cylindrical portion 71a in the cylindrical portion 71a. The outer flange portion 71b faces the periphery of the opening on the installation surface.
The frame body 71 has an inner flange portion 71d that protrudes inward from the back side end of the cylindrical portion 71a. The engaging portion 61d of the reflecting portion 6 is engaged with the inner flange portion 71d in a state where the outer flange portion 61c of the reflecting member 61 is fitted to the stepped portion 71c of the frame body 71. Thereby, the reflection part 6 is attached to the frame part 7 without rattling.

Second Embodiment
The heat radiating part 3 in the first embodiment is configured separately from the cylindrical body 33 and the fins 35. The heat radiating part should just be provided with the cylindrical body and the fin.
In the second embodiment, a heat radiating portion integrally including a cylindrical body and fins will be described with reference to FIGS. 6 and 7.
The heat radiating portion 103 includes a mounting member 131, a finned tubular body 134, and a lid member 137. It should be noted that both the front and back ends of the finned tubular body 134 are closed by the mounting member 131 and the lid member 137, and the inside is filled with a working fluid (not shown), the tubular portion 133, the mounting member 131, and the lid The member 137 has a heat pipe function.

1. Mounting Member The mounting member 131 mainly closes the front side opening of the finned tubular body 134. In addition, it can be said that it is a bottom member when the light source part 2 is not directly mounted on the surface.
The mounting member 131 has a plate-like portion 131a. As shown in FIG. 7A, the mounting member 131 has an annular groove 131 b in a portion of the plate-like portion 131 a that faces the front end surface of the finned cylindrical body 134. A ring-shaped packing 141 is disposed in the groove 131b.
The mounting member 131 has a fixing portion 131 c for fixing the mounting member 131 to the front end portion of the finned tubular body 134. A screw (not shown) is used for fixing here, and as shown in FIG. 6B, the fixing portion 131c is formed by a through hole.
The mounting member 131 is made of a metal material, for example, copper. Here, the mounting member 131 has a rectangular shape when viewed from the front side.

2. Lid member The lid member 137 mainly closes the back side opening of the finned tubular body 134. The lid member 137 has a plate-like portion 137a. As shown in FIG. 7A, the lid member 137 has an annular groove 137b in a portion of the plate-like portion 137a facing the back side end surface of the finned tubular body 134. A ring-shaped packing 141 is disposed in the groove portion 137b.
The lid member 137 has a fixing portion 137c for fixing the lid member 137 to the back side end portion of the finned tubular body 134. A screw (not shown) is used for fixing here, and the fixing portion 137c is constituted by a through hole.
The lid member 137 has a communication hole 137d in a portion capable of communicating with the inside of the tubular body 134 with a fin (sa) in FIG. 7, and has a cylindrical portion 137e extending from the periphery of the communication hole 137d to the back side. . The communication hole 137d and the cylindrical portion 137e are used when the inside of the heat pipe is decompressed, as in the first embodiment. In addition, the cylinder part 137e of FIG.6 and FIG.7 is a state before sealing.

3. Finned Tubular Body Finned tubular body 134 includes a tubular portion 133 and a fin portion 135 integrally.
Here, the cylindrical portion 133 has a cylindrical shape. The inner peripheral surface 133a of the cylindrical portion 133 is roughened.
The fin portion 135 includes a plurality of fins 135a. The plurality of fins 135a are provided in parallel at equal intervals in the circumferential direction. The fin 135a extends in the radial direction across the front and back ends of the outer peripheral surface of the cylindrical portion 133. Here, the fin 135a extends in an arc shape. Thereby, for example, an extruded product of aluminum can be used as the finned cylindrical body 134.
The finned cylindrical body 134 has a mounting portion 131 and a fixing portion for the lid member 137. Here, a screw (not shown) is used for fixing, and the fixing portion is constituted by a screw groove 135b. As shown in FIG. 7 (b), the thread groove 135b uses a groove between the roots of the fin portion 135 (sites close to the cylindrical portion 133), and at the front and back end portions in the cylindrical axis direction of the groove. It is threaded.

<Third Embodiment>
A plurality of fins 35 in the first embodiment and fins 135a in the second embodiment are provided at intervals in the circumferential direction. The heat dissipating part only needs to include a cylindrical body and fins, and the fins may not be provided at intervals in the circumferential direction.
In 3rd Embodiment, the thermal radiation part 203 in which a fin is provided in the cylinder axis direction of a cylindrical body at intervals is demonstrated using FIG.
The heat radiation unit 203 includes a bottom member 231, a cylindrical body 233, fins 235, and a lid member 237. In addition, in the case where the front and back both ends of the cylindrical body 233 are closed by the bottom member 231 and the lid member 237 and the inside is filled with the hydraulic fluid, the tubular body 233, the bottom member 231 and the lid member 237 are heat pipes. Is configured. When the light source unit is mounted on the bottom member 231, the bottom member also functions as a mounting member.

Here, the cylindrical body 233 has a cylindrical shape.
The bottom member 231 has a disk-shaped plate portion 231a and a columnar portion 231b having a diameter smaller than the diameter of the plate portion 231a, and the columnar portion 231b is inserted into and fitted into the front side end portion of the cylindrical body 233. .
The lid member 237 has a cylindrical plate portion 237a, a cylindrical portion 237b having a diameter smaller than the diameter of the plate portion 237a, and a communication cylinder portion 237c provided on the back surface of the plate portion 237a and communicating with the front side. The cylindrical portion 237b is inserted and fitted into the back side end portion of the cylindrical body 233.

The bottom member 231 has a partition plate portion 231c that partitions the inside of the cylindrical body 233 in a direction parallel to the cylinder axis on the back surface of the cylindrical portion 231b. That is, the bottom member 231 has a partition plate portion 231c that stands up from the cylindrical portion 231b to the front of the lid member 237. In addition, the partition plate part 231c has a through hole 231d for making the amount of the hydraulic fluid uniform in a portion located in the hydraulic fluid.
During the lighting, the partition plate portion 231c circulates between the liquid working fluid and the heated and vaporized working gas across the partition plate portion 231c. Thereby, the working fluid and the working gas do not interfere with each other, and the heat dissipation efficiency can be improved.
In addition, you may apply the partition plate part 231c to the inside of the cylindrical body 33 of 1st Embodiment, and the inside of the cylindrical body 134 with a fin of 2nd Embodiment.
Even in this case, the liquid working fluid and the heated working gas can be circulated across the partition plate portion 231c, and the interference between the working fluid and the working gas can be suppressed to enhance the heat dissipation effect. Can contribute.

  The plurality of fins 235 are configured by pressing a metal plate. The fins 235 are provided at intervals in the cylinder axis direction of the cylindrical body 233. The fin 235 has a plate shape and includes a fin portion 235a having an opening 235b in the center, and a flange portion 235c projecting from the periphery of the opening 235b of the fin portion 235a to the front side or the back side. The interval between the plurality of fin portions 235a is defined by the protruding amount of the flange portion 235c.

<Results>
The heat dissipation performance of the heat dissipation part described in the first and second embodiments was tested.
In the test, the same light source part was mounted on the surface of the heat radiating part, and the cathode temperature of the LED element when it was lit under the same conditions was measured.
There are a total of four heat dissipating parts used in the test: Comparative Example, Example 1, Example 2, and Example 3. The comparative example is a heat sink described in Patent Document 1 described in the related art, and is an aluminum die-cast product.
In Example 1, the cylindrical body 33 and the fin 35 described in the first embodiment are separate heat radiating portions 3, and the bent portion 35 c of the fin 35 is in close contact with the groove 33 b of the cylindrical body 33. Inserted and crimped at both ends of the cylindrical body 33 in the cylindrical axis direction. In addition, the inner surface of the cylindrical body 33 is not roughened.
In Example 2, the cylindrical body 33 and the fins 35 described in the first embodiment are the heat dissipating part 3, and the bent portion 35 c of the fin 35 has a gap (0. 1 [mm]), and is crimped at both ends of the cylindrical body 33 in the cylindrical axis direction. In addition, the inner surface of the cylindrical body 33 is not roughened.
Example 3 is the heat radiating part 103 in which the cylindrical part 133 and the fin part 135 are integrated as described in the second embodiment. In addition, the inner surface of the cylindrical part 133 is not roughened.
Example 4 is the heat radiating unit 3 described in the first embodiment, in which the cylindrical body 33 and the fins 35 are separate and the inner surface of the cylindrical body 33 is roughened.
As shown in FIG. 10, the measurement results show that Examples 1 to 4 in which fins are provided on the heat pipe have better heat dissipation characteristics than the heat sink of the conventional aluminum die cast product.
The difference between the first and second embodiments is the adhesion (contact area) between the cylindrical body 33 and the fins 35. It can be seen that Example 1 with a large contact area has better heat dissipation characteristics than Example 2 with a small contact area.
The difference between the third and fourth embodiments is whether or not the inner peripheral surface of the cylindrical body 33 is roughened. It can be seen that the roughened Example 4 has better heat dissipation characteristics than the non-roughened Example 2.

Although the embodiment has been described above, the present invention is not limited to this embodiment, and for example, the following modification may be used. Further, the embodiment may be a combination of the modified example and the modified examples.
In addition, examples that are not described in the embodiments and modifications, and design changes that do not depart from the gist are also included in the present invention.

<Modification>
1. Mounting Member The surfaces of the mounting members 31 and 131 and the bottom member 231 are flat. However, when the light source unit is mounted, it is only necessary to have a flat portion in the region where the light source unit is mounted. For example, the portion on which the light source unit is mounted may be a recessed portion, and the light source portion may be mounted on the flat bottom surface of the recessed portion. Moreover, when mounting a light source part via a thermal sheet, flatness may be lower than the case where a light source part is mounted directly.
The mounting members 31 and 131 and the bottom member 231 are not particularly limited as long as both ends of the cylindrical bodies 33 and 233 constituting the heat pipe can be closed in an airtight manner.
A portion functioning as a heat pipe in the mounting member (a portion in contact with the working fluid and the working gas) may be roughened or may have an oxide film.

2. Cylindrical body (1) Inner peripheral shape In the cross-sectional shapes of the cylindrical bodies 33, 233 and the finned cylindrical body 134, the inner peripheral shape is circular, but the inner peripheral shape is, for example, a circle as a whole. It may be a shape or a polygonal shape, and the periphery may have a triangular wave shape (sawtooth shape), a rectangular wave shape, or a sine wave shape. The inner peripheral shape in the cross-sectional shape may be a star shape or a “+” shape. In addition, the shape which can enlarge the space filled with a hydraulic fluid and an internal peripheral area becomes large is preferable.

(2) Perimeter shape (separate from fins)
In the cross-sectional shape of the cylindrical bodies 33, 233, the outer peripheral shape was circular, but the shape is not particularly limited as long as it has a structure to which fins are attached or attached, for example, Polygonal shape, star shape, etc. may be sufficient.

3. Fins The shapes and structures of the fins 35 and 235 and the fin portion 135 described in the embodiment are merely examples, and other shapes may be used.
(1) 1st Embodiment Although the fin 35 processed the thin metal plate into "V" shape (sheet metal), for example, it processed into "L" shape, "W" shape, and "U" shape. It may be a fin. Moreover, the shape curved in circular arc shape like 2nd Embodiment may be sufficient.
The fin 35 is inserted into the groove 33 b of the cylindrical body 33. From the viewpoint of heat dissipation, it is preferable that the bent portion 35c of the fin 35 and the groove 33b are in contact over a wide range.

(2) Second Embodiment The fin portion 135 has an arc shape when viewed from the cylinder axis direction, but may be a straight line or a “V” shape as in the first embodiment. Also good. In addition, when providing a fin part integrally in a cylindrical part and utilizing an extruded product, it is necessary to make cross-sectional shape the same in an extrusion direction.

(3) Third Embodiment Although the fin 235 has the opening 235b and the flange portion 235c, for example, a plate-like fin having an opening in the center and a cylindrical body corresponding to the flange portion 235c are alternately arranged. You may make it overlap.
The fins 235 are provided in a state orthogonal to the cylinder axis of the cylindrical body 233, but may be provided in an inclined state with respect to the cylinder axis, for example. For example, you may make it incline in the range of 30-60 [degrees] with respect to a cylinder axis, for example, 45 [degrees]. Thereby, the air heated by the fin rises while exchanging heat along the fin, and the heat dissipation effect can be enhanced.
In this case, the rough surface processing which increases a surface area may be given to the upper surface side of a fin. In addition, when providing a fin in inclination, it can implement by providing a collar part so that it may incline with respect to the cylinder axis | shaft of a cylindrical body.

  The fins of the third embodiment and the fins (except for the flanges) that are inclined with respect to the cylinder axis described in this modification have a linear flat plate shape, but, for example, heated air does not stay there. It may be curved in a range, or for example, may have a shape that moves upward as it moves away from the center, such as a disc spring.

  The fins 35 and 235 and the fin part 135 may be provided on the heat pipe, may be provided separately on the heat pipe (cylindrical body), may be provided integrally, or may be partly integrated. The fins may be provided separately in other parts. Thereby, the finned cylindrical body integrally including the fins can be used as a standard type, and the fins can be additionally attached corresponding to the amount of heat generated by the light source unit, and the parts can be shared.

4). Lid member Lid members 37, 137, and 237 are not particularly limited as long as both ends of cylindrical bodies 33 and 233 constituting the heat pipe can be sealed in an airtight manner.
The cylindrical portions 37e, 137e and the communicating cylindrical portion 237c of the lid members 37, 137, 237 are sealed using caulking, but may be sealed by other methods, for example, a molten glass frit. It may be sealed by welding, sealed by brazing, or a combination thereof. In addition, copper solder, brass solder, etc. can be used as the solder.

5. Attaching the bottom member and the lid member to the tubular body In the embodiment, the fitting portion is fixed using screws 81 and 83 via packing, but other methods may be used as long as they are attached in an airtight manner.
As another method, it may be attached by brazing disposed between the end face and bottom member of the cylindrical body and the end face of the cylindrical body and the lid member, may be attached by welding, or may be attached by press-fitting. These may be combined.

DESCRIPTION OF SYMBOLS 1 Illuminating device 2 Light source part 3 Heat radiating part 31 Mounting member 33 Cylindrical body 35 Fin 37 Cover member

Claims (5)

A light source unit including a light emitting element as a light source;
A heat dissipating part mounting the light source part on the front side,
The heat dissipation unit includes a heat pipe and a plurality of fins provided on the heat pipe. The lighting device according to claim 1, wherein the plurality of fins are integrally molded with the heat pipe. The fin is made of a metal plate,
The lighting device according to claim 1, wherein the plurality of fins are attached to the heat pipe. The lighting device according to claim 1, wherein an inner surface of the heat pipe is a rough surface. The lighting device according to claim 1, wherein the plurality of fins are provided on the heat pipe along a direction in which an axis of the heat pipe extends.

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