JP2016115649A - LED lamp - Google Patents

Abstract

PROBLEM TO BE SOLVED: To attain weight saving of a heat sink and an LED substrate, and facilitate a step of assembling the heat sink and the LED substrate, in a bulb type LED lamp.SOLUTION: An LED lamp has a mouthpiece, an LED substrate having a polygonal cross section and formed into a cylindrical shape, and an LED element mounted on the outside of the LED substrate. The LED substrate is arranged along a center axial line of the lamp passing through the mouthpiece, and may be formed by folding a sheet of rectangular substrate along a folding part.SELECTED DRAWING: Figure 5

Description

  The present invention relates to an LED lamp, and more particularly to a bulb-type LED lamp having an LED cooling mechanism.

  LED lamps using light emitting diodes (hereinafter referred to as LEDs) as light sources are widely used. In recent years, with the expansion of the use of LED lamps, there is a demand for higher output and higher power of LED lamps. The LED lamp has an advantage of having a high luminous efficiency as compared with the discharge lamp, but has a disadvantage that the luminous efficiency is lowered when the LED is heated to a high temperature. Therefore, an LED cooling mechanism for cooling the LED is provided in order to prevent the LED from becoming hot. Examples of the LED cooling mechanism include a heat sink and a cooling fan.

  Patent Document 1 describes an example of a bulb-type LED lamp. This LED lamp has a hexagonal cylindrical heat sink, and an LED substrate is mounted on the outer surface thereof. Radiation fins are provided inside the heat sink. Patent Document 2 describes an example of a light-emitting module having a foldable wiring board on which a light-emitting element is mounted and a plate-like base material that supports the wiring board. A V-shaped groove is formed in the plate member.

JP 2012-156036 JP 2011-249534

  In order to increase the luminous efficiency of the LED lamp, a high performance heat sink having good heat conduction characteristics and heat radiation characteristics is required. In general, high performance heat sinks have a relatively large profile and weight. In the conventional technique, the LED substrate is attached to the heat sink with screws or the like. As a result, the LED lamp becomes larger and its weight increases. When the weight of the heat sink and the LED substrate is reduced, not only the heat conduction characteristics and the heat dissipation characteristics are deteriorated, but also the operation of mounting the heat sink on the LED board becomes relatively difficult. Therefore, in the light bulb-type LED lamp, there is a demand for facilitating the process of assembling the heat sink and the LED substrate together with reducing the weight of the heat sink and the LED substrate.

  An object of the present invention is to facilitate the process of assembling a heat sink and an LED substrate together with reducing the weight of the heat sink and the LED substrate in a light bulb type LED lamp.

  The inventors of the present application have conceived a structure in which a heat sink is attached to the LED substrate instead of attaching the LED substrate to the heat sink by screws or the like. Further, the LED substrate is formed by bending one substrate. As a result, it has been found that the process of assembling the heat sink and the LED substrate can be facilitated while the heat sink and the LED substrate are reduced in weight.

  According to this embodiment, the LED lamp has a base, an LED substrate having a polygonal cross section and formed in a cylindrical shape, and an LED element mounted on the outside of the LED substrate, and the LED substrate. Are arranged along the central axis of the lamp passing through the base, and the LED substrate may be formed by bending a rectangular substrate along a bent portion.

  According to the present embodiment, in the LED lamp, the LED board may have a thin long hole or a slit along the bent portion.

  According to this embodiment, in the LED lamp, the LED substrate may have a V-groove along the bent portion on the surface opposite to the surface on which the LED element is mounted.

  According to this embodiment, in the LED lamp, the angle of the V groove may be equal to the outer angle of the polygon.

  According to this embodiment, in the LED lamp, the thickness of the LED substrate in the deepest part of the V groove may be 0.2 to 0.6 mm.

  According to the present embodiment, in the LED lamp, a heat sink mounted inside the LED substrate, a through hole formed inside the heat sink, a cooling fan disposed between the base and the heat sink, A light-transmitting cover provided with an air discharge hole, and cooling air from the cooling fan is guided to a through hole inside the heat sink and is externally passed through the air discharge hole of the cover. At the same time as the discharge, the elongated hole may flow into the space between the LED substrate and the cover or through a slit.

  According to the present embodiment, in the LED lamp, the heat sink has a plurality of heat radiation fins extending so as to protrude into the through hole, and is formed by bending a thin plate member. It's okay.

  According to this embodiment, in the LED lamp, the heat sink and the end of the LED substrate may be sandwiched and fixed between clips.

  According to this embodiment, in the LED lamp, the heat sink and the LED substrate may be further fixed by rivets.

  ADVANTAGE OF THE INVENTION According to this invention, the process of assembling a heat sink and an LED board can be simplified with the weight reduction of a heat sink and an LED board in a light bulb type LED lamp.

FIG. 1A is a perspective view illustrating a configuration example of an LED lamp according to the present embodiment. FIG. 1B is a perspective view illustrating a configuration example of the LED lamp according to the present embodiment. FIG. 2 is an exploded perspective view of the LED lamp according to the present embodiment. FIG. 3 is a perspective view for explaining the structure of the LED unit and the spacer of the LED lamp according to the present embodiment. FIG. 4 is an explanatory diagram illustrating a cooling air flow in the LED lamp according to the present embodiment. FIG. 5 is an explanatory diagram illustrating the structure of the LED unit of the LED lamp according to the present embodiment. FIG. 6A is an explanatory diagram illustrating an example of the structure of the LED substrate of the LED unit of the LED lamp according to the present embodiment. FIG. 6B is an explanatory diagram illustrating an example of the structure of the LED substrate of the LED unit of the LED lamp according to the present embodiment. FIG. 6C is an explanatory diagram illustrating an example of the structure of the LED substrate of the LED unit of the LED lamp according to the present embodiment. FIG. 7 is an explanatory view illustrating an example of the structure of the heat sink of the LED unit of the LED lamp according to the present embodiment. FIG. 8A is an explanatory diagram illustrating an example of a clip structure of the LED unit of the LED lamp according to the present embodiment. FIG. 8B is an explanatory diagram illustrating an example of a clip structure of the LED unit of the LED lamp according to the present embodiment. FIG. 9A is an explanatory diagram illustrating an example of a method for assembling the LED substrate of the LED unit of the LED lamp according to the present embodiment. FIG. 9B is an explanatory diagram illustrating an example of a method for assembling the LED substrate of the LED unit of the LED lamp according to the present embodiment. FIG. 9C is an explanatory diagram illustrating an example of the structure of the fixing portion of the LED substrate and the heat sink of the LED unit of the LED lamp according to the present embodiment. FIG. 10A is an explanatory diagram illustrating an example of a side surface of a cylindrical LED substrate of an LED unit of an LED lamp according to the present embodiment. FIG. 10B is an explanatory diagram illustrating a cross-sectional configuration of a cylindrical LED substrate of the LED unit of the LED lamp according to the present embodiment. FIG. 11A is an explanatory diagram illustrating an example of a planar configuration of the LED substrate of the LED lamp according to the present embodiment. FIG. 11B is an explanatory diagram illustrating a cross-sectional configuration of the V groove of the LED substrate of the LED lamp according to the present embodiment.

  Hereinafter, embodiments of an LED lamp according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted.

  An example of the LED lamp according to the present embodiment will be described with reference to FIGS. 1A and 1B. As shown in FIG. 1A, the LED lamp 10 includes a base 13, a connecting member 19 connected to the base 13, a case 20 attached to the connecting member 19, and a cylindrical transparent piece attached to the case 20. And a light cover 41. An LED unit 30 is disposed inside the cover 41. The LED lamp according to this embodiment is a so-called bulb type. Hereinafter, the direction toward the base 13 or the direction close to the base 13 along the central axis of the lamp passing through the base 13 will be referred to as the base side, and the opposite will be referred to as the top side.

  The housing 20 includes a cylindrical portion 21 on the base side, a fan storage portion 23 on the top side, and an air intake portion 24 therebetween. The cylindrical portion 21 and the fan accommodating portion 23 have a substantially cylindrical outer surface, and the outer diameter of the fan accommodating portion 23 is larger than the outer diameter of the cylindrical portion 21. The cylindrical outer surfaces of the cylindrical portion 21 and the fan storage portion 23 may be inclined along the axial direction so that the outer diameter slightly decreases toward the base side. The air intake 24 has an opening for taking in cooling air. As shown in FIG. 1B, the LED lamp 10 further includes a ring-shaped vibration isolating member 14 that covers a part of the base 13 and the connecting member 19.

  With reference to FIG. 2, the internal structure of the LED lamp 10 according to the present embodiment will be described in detail. The LED lamp includes a cover 41, an LED unit 30, a spacer 18, a cooling fan 15, a circular circuit board 27, a housing 20, a connection member 19, a base 13, and a vibration isolation member 14. A plurality of air discharge holes 42 are formed at the top side end of the cover 41. The air discharge holes 42 are arranged concentrically so as to surround the central axis of the LED lamp. The structures of the LED unit 30, the spacer 18, and the cooling fan 15 will be described later. The cooling fan 15 may typically be an axial fan having a motor and rotating blades provided around the motor. The motor may be a direct current brushless motor.

  The housing 20 includes a cylindrical portion 21 on the base side, an air intake portion 24 on the top side, and an intermediate fan storage portion 23. The air intake portion 24 is provided with a plurality of air inlets 242 along the circumferential direction. The circuit board 27 is disposed in the air intake portion 24 of the housing 20. The circuit board 27 includes a lamp protection circuit that stops the supply of current to the LED element when the temperature of the LED element rises, and a fan drive circuit that supplies a direct current to the cooling fan 15. The cooling fan 15 is disposed in the fan storage portion 23 of the housing 20. The spacer 18 is mounted in the fan storage portion 23 of the housing 20. The spacer 18 is made of resin. Further, the LED unit 30 is mounted so as to engage with the spacer 18. Thus, when the circuit board 27, the cooling fan 15, the spacer 18, and the LED unit 30 are mounted, the cover 41 is mounted so as to cover the LED unit 30.

  An example of the structure of the LED unit 30, the spacer 18, and the cooling fan 15 will be described with reference to FIG. The LED unit 30 includes an LED substrate 31 formed in a cylindrical shape and a heat sink 32 attached to the inner surface thereof. The LED substrate 31 is disposed so as to be parallel to and surround the central axis of the LED lamp. The LED substrate 31 includes a cylindrical wiring substrate 311 and a plurality of LED elements 312 mounted on the outer surface thereof.

  The heat sink 32 is attached in close contact with the inner surface of the LED substrate 31 so as to be in surface contact. The heat sink 32 has a plurality of heat radiation fins 322. The fins 322 extend along the central axis of the LED lamp. The shape of the fin 322 is not particularly limited. A through hole 33 through which an air flow passes is formed inside the heat sink 32. The heat sink 32 is manufactured by sequentially bending one rectangular thin metal plate member. The heat sink 32 is made of a metal having high thermal conductivity, for example, copper, aluminum alloy, stainless steel, or the like.

  In the illustrated example, the LED substrate 31 is formed in a cylindrical body having a regular octagonal cross section. However, in the present embodiment, the LED substrate 31 is not limited to the illustrated example, and may be formed in a cylindrical body having a regular polygon other than a regular octagon in cross section. The LED substrate 31 is formed by bending one plate-like rectangular LED substrate in order along the seven bent portions 319 and forming it into a cylindrical shape. Accordingly, a gap 31A is formed between both edges of the cylindrical LED substrate. The LED substrate 31 has thin elongated holes 315 along the seven bent portions 319.

  The LED substrate 31 and the heat sink 32 are fixed by a clip 35 at a top side end (upper end in FIG. 3). Further, the LED substrate 31 and the heat sink 32 are fixed by a rivet 37 at a substantially central position in the axial direction. The clips 35 and rivets 37 are provided at a total of eight locations for each surface of the regular octahedron.

  The spacer 18 includes a center member 181 and an annular member 183 around the center member 181. The central member 181 and the annular member 183 are connected by a radial support member 185. An annular through hole 186 is formed between the center member 181 and the annular member 183. The center member 181 includes a circular member 181A provided on the top side end surface and a cylindrical member 181B that supports the circular member 181A. The annular member 183 has an annular top side end surface 183A and a cylindrical inner surface 183B. An engaging member 187 is provided on the top side end surface 183A.

  The through hole 186 of the spacer 18 has a cross-sectional area that increases from the base side to the top side. At least one of the cylindrical inner surface 183B of the annular member 183 and the cylindrical member 181B of the center member 181 is inclined along the axial direction. In the illustrated example, the diameter of the cylindrical inner surface 183B of the annular member 183 increases toward the top side. Furthermore, the outer diameter of the cylindrical member 181B of the center member 181 may be increased toward the top side.

  The cooling fan 15 has a central cylindrical motor 151 and a cylindrical member 153 around it, and an annular through hole 156 is formed between them. A rotating blade is disposed in the through hole 156. The motor 151 and the cylindrical member 153 are connected by a radial support member 155.

  The motor 151 of the cooling fan 15 and the central member 181 of the spacer 18 have corresponding shapes and dimensions and are arranged to align along the central axis of the lamp. For example, the motor 151 of the cooling fan 15 and the circular member 181A of the central member 181 of the spacer 18 may be formed to have the same outer diameter. Further, the end surface on the base side of the motor 151 of the cooling fan 15 and the cylindrical member 181B of the central member 181 of the spacer 18 may be formed to have the same outer diameter.

  The support member 155 of the cooling fan 15 and the support member 185 of the spacer 18 have corresponding shapes and dimensions, and are arranged in alignment along the central axis of the lamp. For example, when the cooling fan 15 includes four support members 155, the spacer 18 includes four support members 185.

  The through hole 156 of the cooling fan 15 and the through hole 186 of the spacer 18 have corresponding shapes and dimensions, and are arranged in alignment along the central axis of the lamp. For example, the top opening of the through hole 156 of the cooling fan 15 and the base opening of the through hole 186 of the spacer 18 may be formed to have the same shape. A continuous tubular air flow path is formed by the through hole 156 of the cooling fan 15 and the through hole 186 of the spacer 18. This air flow path is connected to a through hole 33 inside the heat sink 32.

  The LED unit 30 is mounted on the annular member 183 of the spacer 18. The base end (lower end in FIG. 3) of the LED substrate 31 is in contact with the top end surface 183A of the annular member 183 of the spacer 18 and is held by the engaging member 187. The engaging member 187 may have a claw shape as illustrated, but may have another shape.

  The inventor of the present application intensively studied a preferable shape of the central member 181 of the spacer 18. The inventor of the present application prepares a spacer 18 having a tubular center member 181 and a spacer 18 having a bottomed cylindrical container-shaped center member 181, and is mounted on the LED lamp shown in FIG. Went. As a result, the use of the spacer 18 with the bottomed cylindrical container-shaped center member 181 is more effective for cooling the motor 151 of the cooling fan 15 than when the spacer 18 with the tubular center member 181 is used. I found out. Furthermore, the case where the circular member 181A is provided on the top side of the cylindrical member 181B in the central member 181 was compared with the case where it was provided on the base side. As a result, it has been found that it is advantageous to cool the motor 151 of the cooling fan 15 by providing the circular member 181A on the top side of the cylindrical member 181B. Therefore, in this embodiment, the center member 181 is formed in a bottomed cylindrical container shape having a circular member 181A and a cylindrical member 181B as shown in FIG.

  With reference to FIG. 4, the air cooling system of the LED lamp which concerns on this embodiment is demonstrated. FIG. 4 shows a cross-sectional structure along the axial direction of the LED lamp according to the present embodiment. The base side end portion of the cover 41 is connected to the top side end surface of the fan storage portion 23 of the housing 20. The LED unit 30, the spacer 18, and the cooling fan 15 are disposed in a space formed by the cover 41 and the fan storage portion 23. The LED unit 30, the spacer 18, and the cooling fan 15 are arranged in alignment along the central axis of the lamp. The fins 322 of the heat sink 32 extend along the axial direction from the base side end of the heat sink 32 to the top side end.

  In the present embodiment, the spacer 18 is disposed between the cooling fan 15 and the heat sink 32. That is, a space for arranging the spacer 18 is formed between the cooling fan 15 and the heat sink 32. In the present embodiment, a space is provided between the cooling fan 15 and the heat sink 32, and the spacer 18 is disposed in this space to prevent heat from the heat sink 32 from being transmitted to the motor 151 of the cooling fan 15. Is done.

  The inner diameter of the through hole 33 of the heat sink 32 is larger than the outer diameter of the through hole 156 of the cooling fan 15. That is, there is a difference between the cross section of the through hole 33 of the heat sink 32 and the cross section of the through hole 156 of the cooling fan 15. The spacer 18 has a function of reducing this difference. As shown in the figure, the cylindrical inner surface 183B of the annular member 183 of the spacer 18 is inclined, and its diameter increases from the base side to the top side. That is, the cross section of the through hole 186 of the spacer 18 increases from the base side to the top side. Accordingly, the difference between the cross section of the through hole 33 of the heat sink 32 and the cross section of the through hole 156 of the cooling fan 15 is alleviated by a change in the cross section of the through hole 186 of the spacer 18. In the present embodiment, by providing the spacer 18, the cooling air generated by the cooling fan 15 can be efficiently guided to the through hole 33 of the heat sink 32.

  The air intake portion 24 of the housing 20 includes a plurality of support members 241 that bridge the cylindrical portion 21 and the fan storage portion 23. An air inlet 242 is formed between these support members 241. The support member 241 has a substantially triangular shape, and a virtual conical surface that includes the outer surface of the hypotenuse in common is formed. The fan housing part 23 of the housing 20 has a cylindrical part 23A and a bottom part 23B. An air suction hole 231 is formed in the bottom surface portion 23B.

  The path of the cooling air flow of the LED lamp according to this embodiment will be described. Arrows indicate the path of the cooling air flow. The air intake port 242 of the air intake portion 24 of the housing 20, the air suction hole 231 of the bottom surface portion 23 </ b> B of the fan housing portion 23 of the housing 20, the through hole 156 of the cooling fan 15, the through hole 186 of the spacer 18, and the heat sink 32. The through hole 33 and the air discharge hole 42 of the cover 41 are arranged in alignment along the axial direction of the lamp, and form one continuous air flow passage. Further, the through hole 33 of the heat sink 32, the long hole 315 and the gap 31A (FIG. 3) of the LED substrate 31, the space 43 between the cover 41 and the LED substrate 31, and the air discharge hole 42 of the cover 41 are arranged along the axis of the lamp. One continuous air flow passage is formed around.

  When the cooling fan 15 is rotated, an axial cooling airflow is first formed in the annular through hole 156. At this time, cooling air having a relatively low temperature is taken in from the external space via the air intake port 242 of the air intake portion 24 of the housing 20. The cooling air is guided to the through hole 156 of the cooling fan 15 via the air suction hole 231 of the bottom surface part 23 </ b> B of the fan housing part 23. Since the motor 151 of the cooling fan 15 is cooled by the cooling air having a relatively low temperature from the external space, it is possible to avoid the performance deterioration of the cooling fan 15 due to the deterioration of the lubricating oil of the motor 151.

  Cooling air taken in through the air intake port 242 of the air intake 24 of the housing 20 flows into the space where the circuit board 27 is arranged. Thereby, the circuit board 27 arranged in the air intake portion 24 is always radiated efficiently. Therefore, it is possible to prevent deterioration and malfunction due to high temperature of circuit components and the like.

  The cooling air flow generated by the cooling fan 15 is guided to the through hole 33 of the heat sink 32 via the through hole 186 of the spacer 18. When the cooling air contacts the heat sink 32, heat exchange is performed. The cooling air takes heat away from the heat sink 32 and its temperature rises. The air having a relatively high temperature after cooling passes through the through hole 33 and is discharged from an air discharge hole 42 provided at the top side end of the cover 41.

  A part of the cooling air guided to the through hole 33 of the heat sink 32 flows into the space 43 between the cover 41 and the LED substrate 31 via the long hole 315 and the gap 31A (FIG. 3) of the LED substrate 31. Then, it is discharged from the air discharge hole 42 beyond the top side end portion of the LED substrate 31. Therefore, the air in the space 43 between the cover 41 and the LED substrate 31 is always replaced with new cooling air. The wiring board 311 and the LED element 312 are cooled by the cooling air flowing into the space 43.

  According to the present embodiment, the space through which the cooling air passes forms a sealed space except for the air intake port 242 of the air intake portion 24 of the housing 20 and the air discharge hole 42 of the cover 41. Therefore, all the cooling air introduced from the external space efficiently passes through the through holes 33 and the space 43 of the heat sink 32 and is used for cooling the heat sink 32 and the LED substrate 31. Therefore, the heat sink 32 and the LED substrate 31 in surface contact with the heat sink 32 can be efficiently cooled. Thus, the heat sink 32 and the LED substrate 31 are prevented from being heated up.

  With reference to FIG. 5, the example of the attachment structure of the heat sink 32 in the LED unit 30 of this embodiment is demonstrated in detail. As described above, in the present embodiment, the LED substrate 31 is formed by bending one plate-like rectangular LED substrate in order along the seven bent portions 319 and forming it into a cylindrical shape. Accordingly, a gap 31A is formed between both edges of the cylindrical LED substrate. The LED substrate 31 has thin elongated holes 315 along the seven bent portions 319. A hole 313 is formed in each of the central portions of the eight surfaces of the LED substrate 31.

  The structure of the heat sink 32 will be described. The heat sink 32 of the present embodiment includes a mounting portion 321 having a flat mounting surface and a plurality of thin plate-like heat radiation fins 322 extending perpendicularly from the mounting portion 321, and between adjacent fins 322. A recess 324 is formed. A hole 323 is formed near the center of the mounting portion 321. A total of eight heat sinks 32 are provided for each of the eight surfaces of the LED substrate 31. Here, the heat sink 32 is disposed so as not to block the long hole 315 of the LED substrate 31. Instead of using eight heat sinks, a single integrated heat sink in which eight heat sinks 32 are integrated may be used. When an integrated heat sink is used, it is bent in order at seven locations and formed into a cylindrical shape. The integrated heat sink may have a long hole similar to the long hole 315 of the LED substrate 31 along the seven bent portions 319. Details of the structure and manufacturing method of the heat sink 32 will be described later.

  The LED substrate 31 and the heat sink 32 are fixed by a clip 35 at a top side end (upper end in FIG. 5). The clip 35 may have any structure or shape as long as it can be fixed with the edge of the LED substrate 31 and the heat sink 32 interposed therebetween. The clip 35 fixes the LED substrate 31 and the heat sink 32 with a spring force. The spring force is generated by a leaf spring or a wire spring. Details of the clip 35 will be described later. The LED substrate 31 and the heat sink 32 are fixed by a rivet 37 at a substantially central position in the axial direction. The rivet 37 passes through the hole 313 of the LED substrate 31 and the hole 323 of the heat sink 32. The clips 35 and rivets 37 are provided at a total of eight locations for each surface of the regular octahedron.

  With reference to FIG. 6A, FIG. 6B, and FIG. 6C, the example of the LED board 31 of the LED unit 30 of this embodiment is demonstrated. Here, a flat state before the LED substrate 31 is bent and formed into a cylindrical shape is shown. The LED substrate 31 includes a wiring substrate 311 and LED elements 312. In this example, the LED substrate 31 is configured to form a cylindrical body having a regular octagonal cross section. Therefore, the LED substrate 31 includes eight segments, and a rivet hole 313 is formed in each segment. Further, seven bent portions 319 (FIG. 3) are formed between adjacent segments. In the LED substrate 31 of the present embodiment, these bent portions 319 are formed with long holes 315 or notched slits 317 extending to the edges. In the LED substrate shown in FIG. 6A, a long hole 315 is formed in each bent portion 319, and in the LED substrate shown in FIG. 6B, a slit 317 is formed in each bent portion 319. In the LED substrate shown in FIG. 6C, the long holes 315 or the slits 317 are alternately formed in the bent portions 319.

  With reference to FIG. 7, the structure and manufacturing method of the heat sink 32 according to the present embodiment will be described in more detail. The heat sink 32 includes a mounting portion 321 having a flat mounting surface and a plurality of heat radiation fins 322 extending vertically from the mounting portion 321. A recess 324 is formed between the fins 322. According to this embodiment, the heat sink 32 is manufactured by sequentially bending one rectangular thin metal plate-like member. The number of fins 322 is not particularly limited. In the illustrated example, the number is 6, but it may be less or more. The height T of the fins 322 may be different. For example, as shown in the figure, the height of the fins at the center may be larger than the heights of the fins on both sides. The interval L between the adjacent fins 322 may be the same or different. In the case of manufacturing an integrated heat sink including eight heat sinks, similarly, a longer one rectangular thin metal plate-like member is sequentially bent and manufactured.

  The structure and manufacturing method of the clip 35 according to the present embodiment will be described in more detail with reference to FIGS. 8A and 8B. The clip 35 is formed by bending a single metal plate member. The clip 35 has a back portion 351 and claw portions 352 and 353 extending on both sides thereof, and has a substantially U-shaped cross section. The two claw portions 352 and 353 generate a pinching force using a leaf spring. The first claw portion 352 has one elongated shape, but the second claw portion 353 includes three portions. When the clip 35 sandwiches the end portions of the LED substrate 31 and the heat sink 32, the first claw portion 352 presses the LED substrate 31, and the second claw portion 353 presses the heat sink 32. The three portions of the second claw portion 353 press the concave portion 324 of the fin 322. Here, an example of a structure using a leaf spring has been described as an example of the clip 35, but a structure using a wire spring may be used.

  With reference to FIG. 9A, FIG. 9B, and FIG. 9C, the example of the assembly method of the LED unit 30 of this embodiment is demonstrated. As shown in FIG. 9A, eight heat sinks 32, one flat LED substrate 31, and eight rivets 37 are prepared. The LED substrate 31 has a rivet hole 313 and a long hole 315. Further, a V-groove 319A is formed on the surface where the LED element 312 is not mounted as shown in the figure. The V groove 319A and the long hole 315 are formed along the bent portion 319 (FIG. 3).

  A heat sink 32 is attached to each of the eight segments of the LED substrate 31. The width or shape of the heat sink 32 is set so that the long hole 315 of the LED substrate 31 is not blocked by the heat sink. The rivet 37 is inserted into the hole 313 of the LED substrate 31 and the hole 323 (FIG. 5) of the heat sink 32 and pressed. Thus, the heat sink 32 is fixed to the LED substrate 31 by the rivets 37.

  As shown in FIG. 9B, eight clips 35 are prepared. The clip 35 fixes the end of the LED substrate 31 and the end of the heat sink 32. FIG. 9C schematically shows the ends of the LED substrate 31 and the heat sink 32 fixed by the clip 35. The first claw portion 352 of the clip 35 presses the wiring board 311 of the LED substrate, and the second claw portion 353 of the clip 35 presses the mounting portion 321 of the heat sink 32. Finally, the LED board 31 is bent along the seven bent portions 319, whereby the cylindrical LED unit 30 shown in FIG. 3 is formed.

  The structure of the LED substrate 31 will be described with reference to FIGS. 10A and 10B. 10A and 10B are diagrams in which the heat sink 32 is removed from the LED unit 30 shown in FIG. 3 and only the cylindrical LED substrate 31 is taken out. FIG. 10A shows an example of a side configuration of the LED substrate 31, and FIG. 10B is a cross-sectional view showing a planar configuration of the LED substrate 31 taken along line AA in FIG. 10A. The LED substrate 31 includes a wiring substrate 311 and LED elements 312. The LED element 312 is mounted on the outer surface 311A of the wiring board 311.

  As shown in FIG. 10B, in this embodiment, the LED substrate 31 is formed in a cylindrical shape having a regular octagonal cross section. Let θ be the outer angle of a regular octagon. In general, the outer angle of a regular n polygon is obtained by dividing 360 ° by n. That is, θ = 360 ° / n. For example, the outer angle of a regular octagon is θ = 360 ° / 8 = 45 °. In order to form the flat LED substrate 31 into a regular octagonal cylindrical shape, the LED substrate 31 may be bent along the bent portion 319 by an angle equal to the outer angle θ. That is, the outer angle is equal to the bending angle. In the present embodiment, the V-groove 319A is formed along the bent portion 319 on the inner side surface 311B of the wiring board 311 so as to facilitate the bending process and to be accurately bent by the bending angle θ.

  FIG. 11A shows a hole 313, a long hole 315, and a V groove 319 </ b> A formed in the wiring board 311. According to this embodiment, the long hole 315 and the V groove 319 </ b> A are formed along the bent portion of the wiring board 311. Therefore, the LED substrate 31 can be easily and accurately bent along the bent portion. According to the present embodiment, the long hole 315 has a function of guiding a part of the cooling air passing through the through hole 33 to the space 43 between the cover 41 and the LED substrate 31 as described with reference to FIG. At the same time, it has a function of improving the efficiency of bending the LED substrate 31. Note that the slit 317 (FIGS. 6A to 6C) also has the same function as the long hole 315.

  With reference to FIG. 11B, the shape of the V-groove 319A formed in the wiring board 311 will be described. As shown in the figure, the angle formed by the two inner surfaces of the V-groove 319A, that is, the groove angle is θ. In this embodiment, the groove angle θ is set equal to the bending angle. Therefore, when the plate-shaped LED substrate 31 is bent along the bent portion 319, the two inner surfaces of the V groove 319A are in surface contact with each other. Thereby, the shape of the regular polygonal cylindrical LED substrate 31 can be stabilized. The groove angle θ is equal to the outer angle of the regular polygon. For example, when the cross section of the cylindrical LED substrate 31 is a regular octagon, the outer angle is 45 ° and the groove angle θ is 45 °.

  Next, the depth of the V groove 319A will be described. As shown, the thickness of the wiring board 311 is t, the depth of the V-groove 319A is h, and the thickness of the wiring board 311 at the deepest portion of the V-groove 319A is d. In a bending test conducted by the inventors of the present application, it was found that the thickness d is preferably 0.2 to 0.6 mm. If the thickness d is too small, the strength of the LED substrate 31 becomes small, and it becomes difficult to hold the LED substrate in a cylindrical shape. On the other hand, if the thickness d is too large, it is difficult to bend the LED substrate 31 easily.

  As mentioned above, although the LED lamp which concerns on this embodiment was demonstrated, these are illustrations and do not restrict | limit the scope of the present invention. Additions, deletions, changes, improvements, and the like that can be easily made by those skilled in the art with respect to the present embodiment are within the scope of the present invention. The technical scope of the present invention is defined by the appended claims.

DESCRIPTION OF SYMBOLS 10 ... LED lamp, 13 ... Base, 14 ... Anti-vibration member, 15 ... Cooling fan, 18 ... Spacer, 19 ... Connecting member, 20 ... Housing, 21 ... Cylindrical part, 23 ... Fan accommodating part, 23A ... Cylindrical part, 23B ... Bottom part, 24 ... Air intake part, 27 ... Circuit board, 30 ... LED unit, 31 ... LED board, 31A ... Gap, 32 ... Heat sink, 33 ... Through hole, 35 ... Clip, 37 ... Rivet, 41 ... Cover , 42 ... Air exhaust hole, 151 ... Motor, 153 ... Cylindrical member, 155 ... Support member, 156 ... Through hole, 181 ... Center member, 181A ... Circular member, 181B ... Cylindrical member, 183 ... Ring member, 183A ... Top Side end surface, 183B ... cylindrical inner surface, 185 ... support member, 186 ... through hole, 187 ... engaging member, 231 ... air suction hole, 241 ... support member, 242 ... air suction port 311 ... wiring substrate, 312 ... LED element, 313 ... hole, 315 ... long hole, 317 ... slit, 319 ... bending part, 319A ... V groove, 321 ... mounting part, 322 ... fin, 323 ... hole, 324 ... recess, 351 ... back, 352, 353 ... nail

Claims (9)

A base, an LED substrate having a polygonal cross section and formed into a cylindrical shape, and an LED element mounted on the outside of the LED substrate;
The LED substrate is disposed along the central axis of the lamp passing through the base,
The LED substrate is formed by bending a rectangular substrate along a bent portion. The LED lamp according to claim 1, wherein
The LED board according to claim 1, wherein the LED board has a narrow slot or a slit along the bent portion. The LED lamp according to claim 1 or 2,
The LED lamp according to claim 1, wherein the LED substrate has a V-groove along the bent portion on a surface opposite to a surface on which the LED element is mounted. The LED lamp according to claim 3,
The LED lamp according to claim 1, wherein an angle of the V groove is equal to an outer angle of the polygon. The LED lamp according to claim 3 or 4,
The LED lamp having a thickness of 0.2 to 0.6 mm in the deepest portion of the V-groove. The LED lamp according to any one of claims 2 to 5,
A light-transmitting cover provided with a heat sink mounted inside the LED substrate, a through hole formed inside the heat sink, a cooling fan disposed between the base and the heat sink, and an air discharge hole And
Cooling air from the cooling fan is guided to a through hole inside the heat sink and discharged to the outside through the air discharge hole of the cover. At the same time, the long hole or the LED passes through a slit. An LED lamp which flows into a space between a substrate and the cover. The LED lamp according to claim 6,
2. The LED lamp according to claim 1, wherein the heat sink has a plurality of heat dissipating fins extending so as to protrude into the through hole, and is formed by bending one thin plate member. The LED lamp according to claim 6 or 7,
The LED lamp, wherein the heat sink and the end of the LED substrate are fixed by being sandwiched between clips. The LED lamp according to claim 8,
The LED lamp, wherein the heat sink and the LED substrate are further fixed by rivets.

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