JP2016006792A - LED lighting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an LED lighting device which achieves improvement of heat radiation performance from LEDs.SOLUTION: An LED lighting device includes: a heat radiation part 40 which is formed in a direction along a center line with multiple heat radiation fins disposed around the center line; LEDs (light emitting diodes) 23 disposed at the side of the heat radiation part 40 which is opposite to the center line; and a side cover 30 which is fixed to the heat radiation part 40 while covering the LEDs 23. The heat radiation part 40 includes: a side surface formed into a polygonal columnar shape in an area around a center axis; and a protruding part 42 protruding from the side surface in a direction away from the center axis. The side cover 30 is fixed to the heat radiation part 40 while covering the outer side of the side surface. The LEDs 23 are disposed in a space partitioned by the side part, the protruding part 42, and the side cover 30.

Description

  The present invention relates to an LED lighting device such as an LED bulb, and relates to, for example, a small bulb having an E17 base and a mini-krypton bulb.

  A conventional LED bulb is provided with a heat radiating portion having heat radiating fins for heat radiation from the LED.

International Publication No. WO2010 / 089397 Pamphlet International Publication No. WO2010 / 058325 Pamphlet US Patent Application Publication No. 2007/0279906 US Patent Application Publication No. 2011/0089830 Japanese Unexamined Patent Publication No. 2011-070971 US Patent No. 055667036 JP 2011-181248 A International Publication No. WO2010 / 071353 Pamphlet Special table 2007-528588 gazette JP 2011-187161 A

  Provided is an LED lighting device having improved heat dissipation from an LED.

The LED lighting device according to the present invention is:
A heat dissipating part formed in a direction along the center line in a state where a plurality of heat dissipating fins are arranged around the center line;
An LED (light emitting diode) disposed on the opposite side of the heat radiation portion from the center line;
A side cover fixed to the heat dissipating part in a state of covering the LED;
Equipped with.

  In this invention, the heat dissipation from LED increases.

1 is a front view of an LED lighting device 100 according to Embodiment 1. FIG. 1 is a right side view of an LED lighting device 100 according to Embodiment 1. FIG. 1 is a left side view of an LED lighting device 100 according to Embodiment 1. FIG. 1 is a rear view of an LED lighting device 100 according to Embodiment 1. FIG. 1 is a plan view of an LED lighting device 100 according to Embodiment 1. FIG. FIG. 3 is a bottom view of the LED lighting device 100 according to the first embodiment. It is a perspective view from the plane direction of LED lighting apparatus 100 of Embodiment 1. FIG. It is a perspective view from the bottom face direction of LED lighting apparatus 100 of Embodiment 1. FIG. 1 is an exploded perspective view of an LED lighting device 100 according to Embodiment 1. FIG. It is the bottom view which removed the top cover 10 of the LED lighting apparatus 100 of Embodiment 1. FIG. It is AA sectional drawing of the front view of the LED lighting apparatus 100 of Embodiment 1. FIG. It is a lower enlarged view of AA sectional view of LED lighting apparatus 100 of Embodiment 1. It is BB sectional drawing of the right view of the LED lighting apparatus 100 of Embodiment 1. FIG. It is a lower right enlarged view of BB sectional drawing of LED lighting apparatus 100 of Embodiment 1. It is CC sectional drawing of the top view of the LED lighting apparatus 100 of Embodiment 1. FIG. It is a lower right enlarged view of CC sectional drawing of LED lighting apparatus 100 of Embodiment 1. FIG. FIG. 4 is a four-side view of the heat dissipation unit 40 of the first embodiment. 2 is a perspective view of a heat dissipation unit 40 according to Embodiment 1. FIG. It is a related figure of the thermal radiation part 40 of the LED illuminating device 100 of Embodiment 1, power consumption, and LED temperature.

Embodiment 1 FIG.
FIG. 1 is a front view of the LED lighting apparatus 100 of the first embodiment.
FIG. 2 is a right side view of the LED lighting apparatus 100 of the first embodiment.
FIG. 3 is a left side view of the LED lighting apparatus 100 of the first embodiment.
FIG. 4 is a rear view of the LED lighting apparatus 100 according to the first embodiment.
FIG. 5 is a plan view of the LED lighting apparatus 100 according to the first embodiment.
FIG. 6 is a bottom view of the LED lighting apparatus 100 according to the first embodiment.
FIG. 7 is a perspective view from the plane direction of the LED lighting apparatus 100 according to the first embodiment.
FIG. 8 is a perspective view from the bottom surface direction of the LED lighting device 100 according to the first embodiment.

The LED lighting device 100 is, for example, a mini-krypton bulb having an E17 base.
1 to 4 are drawings having the same contents except for the base 80. That is, the LED lighting device 100 has the same shape and appearance from four directions.
The LED lighting device 100 has a circular shape in a plan view, and has a lever-shaped rotating body constricted toward the base 80 as a whole.

  Hereinafter, the radius, the diameter, the arc, the outer circumference, and the inner circumference are the circle radius, the diameter, the arc, or the rotation axis centered on the vertical rotation axis at the center of the LED lighting device 100. It means the outer periphery and inner periphery of the rotating surface.

The lower part of the LED lighting device 100 has a spherical shape, and the diameter gradually decreases from the maximum outer diameter portion toward the base 80.
The LED lighting device 100 has the same shape as or substantially the same shape as a conventional mini-krypton bulb using a commercially available filament, and can be used in place of a conventional commercially available mini-krypton bulb.
The LED lighting device 100 is a light bulb type light emitting diode lamp.

  On the side of the lamp, four radiating fins (the overhanging portion 42 and the fin portion 43) are formed vertically with a substantially constant width from the vicinity of the lower portion of the base 80 to the top cover 10.

  In the light emission direction of the lamp (downward in FIG. 1), one hemispherical top cover 10 is fixed to the lower part of the heat radiating fin (the overhanging portion 42).

  Four side covers 30 are fixed adjacent to the top cover 10 between the lower portions of the four radiating fins (the overhang portions 42).

  Inside the top cover 10 and the side cover 30 is an LED substrate on which a light emitting diode (LED) is mounted.

  A spherical outer shape is formed by the lower part of the four radiating fins (the overhanging portion 42), the one top cover 10, and the four side covers 30.

  A cylindrical housing housing 57 that houses the lighting circuit board is fixed inside the upper portions (fin portions 43) of the four heat dissipating fins.

FIG. 9 is an exploded perspective view of the LED lighting apparatus 100 according to the first embodiment.
FIG. 10 is a bottom view of the LED lighting apparatus 100 according to Embodiment 1 with the top cover 10 removed.
FIG. 11 is an AA cross-sectional view of the front view of the LED lighting apparatus 100 of the first embodiment.
FIG. 12 is a lower enlarged view of the AA cross-sectional view of the LED lighting apparatus 100 of the first embodiment.
FIG. 13 is a BB cross-sectional view of the right side view of LED lighting apparatus 100 of the first embodiment.
FIG. 14 is an enlarged view of the lower right part of the BB cross-sectional view of the LED lighting apparatus 100 of the first embodiment.
FIG. 15 is a CC cross-sectional view of the plan view of the LED lighting apparatus 100 of the first embodiment.
FIG. 16 is an enlarged view of the lower right part of the CC cross-sectional view of the LED lighting apparatus 100 of the first embodiment.
FIG. 17 is a front view, a plan view, a bottom view, and an AA cross-sectional view of the heat radiation unit 40 of the first embodiment. The right side view, left side view, and rear view are the same as the front view, and are omitted.
FIG. 18 is a perspective view from four directions of the heat radiation part 40 of the first embodiment.

Explanation of the heat radiating section 40 (mainly, FIG. 1, FIG. 9, FIG. 12, FIG. 17, FIG. 18)
The LED lighting device 100 includes a heat radiating unit 40. The heat radiation part 40 is aluminum, and is manufactured by a die casting method.

  The heat radiating part 40 has a body part 41, an overhang part 42, and a fin part 43.

The trunk | drum 41 is the lump-shaped aluminum lump which has thickness in the up-down direction (height direction) and a radial direction.
The trunk portion 41 has an outline of a quadrangular prism (regular quadrangular prism) when the trunk portion 41 is considered except for the overhang portion 42. The body portion 41 has an upper surface on the base 80 side and a lower surface on the side opposite to the base 80. The trunk | drum 41 has four side surfaces orthogonal to an upper surface and a lower surface. Adjacent side surfaces of the four side surfaces are also orthogonal. The side surfaces of the lower surface and 4 serve as LED substrate placement portions. From between adjacent side surfaces, projecting portions 42 having a predetermined width project in four directions at intervals of 90 degrees in the radial direction.

  There is a cutout 49 that tapers from the upper surface to the lower surface of the body 41. The shape of the cutout 49 is generally a trumpet shape. The rotation surface of the trumpet-shaped cutout 49 swells smoothly so as to approach the center line of the LED lighting device 100, that is, the center line in the vertical direction of the trunk portion 41.

  For this reason, the trumpet-type cutout can be made thicker in the radial direction (lateral direction) than the cutout of the inverted truncated cone, and the amount of aluminum used can be increased.

  As described above, when the trunk portion 41 is considered except for the overhang portion 42, the outer shape is a quadrangular prism, and the inner shape passes through the center line in the vertical direction of the trunk portion 41. The cross section has an arc-shaped inner peripheral surface 44 (inner peripheral rotation surface) that swells toward the center line. The arc-shaped inner peripheral surface 44 is, for example, a rotating surface obtained by rotating an arc, a parabola, an elliptic arc, or a curve obtained by combining these arcs around the center line of the LED lighting device 100, that is, the center line of the trunk portion 41.

  A stopper 48 that closes the space of the cutout 49 is formed at the tip of the cutout 49.

  In the center of the stopper 48, there is an oval or elongated through hole 45.

  Below the four overhang portions 42 of the body portion 41, corner claw portions 46 whose cross sections are bent in an L shape from the lower surface toward the outer peripheral direction are formed. The corner claw portions 46 are at the lower portions of the four corners on the lower surface of the body portion 41, and are radially inward from the outer periphery of the lower end of the overhang portion 42.

  The outer peripheral surface of the corner claw portion 46 that is bent in an L shape is a spherical surface that bulges outward, and is formed so as to coincide with the concave spherical surface of the inner surface of the top cover 10.

  The corner claw portion 46 bent into an L shape and the lower surface of the body portion 41 provide a U-shaped wedge receiving portion.

  From the upper end portion of the side surface of the trunk portion 41, a convex portion 47 that is convex upward from the upper surface of the trunk portion 41 is formed.

Explanation of the overhanging portion 42 and the fin portion 43 (mainly, FIG. 1, FIG. 9, FIG. 16, FIG. 17, FIG. 18)
The body portion 41 has overhang portions 42 at four corners where two adjacent side surfaces are orthogonal to each other. The overhanging portion 42 protrudes in a convex shape in the radial direction.

The arc length of the outer peripheral surface protruding in a convex shape of the overhanging portion 42 is L2.
The arc length of the outer peripheral surface at the tip of the corner claw portion 46 bent in the L shape at the lower part of the overhang portion 42 is also L2.

  The overhanging portion 42 forms a part of the outer peripheral portion that becomes the outer periphery of the LED lighting device 100. There is a side surface of the trunk portion 41 between the adjacent overhang portions 42, and the LED substrate is disposed. The angle formed between the side surface of the trunk portion 41 and the side surface of the overhang portion 42 is 135 degrees. The side surfaces of the overhang portion 42 are parallel.

  Moreover, the trunk | drum 41 has the fin part 43 which protruded in the direction of the nozzle | cap | die 80 from four corners. The outer peripheral surface of the overhang part 42 and the fin part 43 has a continuous curved surface. The outer peripheral surface of the overhang part 42 and the fin part 43 is an outer peripheral surface that forms an insulator shape of the LED lighting device 100. The outer peripheral surfaces of the overhanging portion 42 and the fin portion 43 are rotating surfaces whose radii smoothly change according to the height direction (vertical direction) of the LED lighting device 100.

  The inner peripheral surface of the fin portion 43 is a rotating surface having a constant radius according to the height direction (vertical direction) of the LED lighting device 100.

  The outer peripheral surface of the overhanging portion 42 has a maximum radius near the upper surface of the body portion 41 or near the upper and lower center of the body portion 41, and the radius gradually decreases toward the lower surface of the body portion 41. The position in the height direction (vertical direction) at which the outer peripheral surface of the overhanging portion 42 has the maximum radius is the same (substantially the same) as the position where the LED 23 of the side substrate 22 is disposed, and heat dissipation from the LED 23 of the side substrate 22. Increases sex.

  The outer peripheral surface of the fin portion 43 has a maximum radius at a portion connected to the overhang portion 42, and the radius is gradually decreased so that the thickness is almost eliminated toward the base 80.

  The inner peripheral surface of the fin portion 43 stands upright from the upper surface of the body portion 41, and the four fin portions 43 provide a cylindrical space. The inner peripheral surface of the fin portion 43 has a rotation surface with a radius R.

The arc length of the outer peripheral surface of the fin portion 43 and the arc length of the inner peripheral surface have the same arc length L2.
Therefore, the fin part 43 has two side surfaces orthogonal to the outer peripheral surface and the inner peripheral surface on the left and right. The two side surfaces of the fin portion 43 are parallel to each other and connected as the same plane as the plane of the overhang portion 42.

The reason why the side surfaces of the fin portion 43 and the side surface of the overhanging portion 42 are not parallel in the transverse section of the fin portion 43 and the overhanging portion 42 is to increase the amount of aluminum used.
The diameter of the inner peripheral surface of the fin portion 43 is the same (or substantially the same) as the opening diameter of the cutout 49 that opens to the upper surface of the body portion 41.

Both the body portion 41, the overhang portion 42, and the fin portion 43 are filled with aluminum, and there are no gaps or spaces inside, so that the amount of aluminum used is increased.
The overhanging portion 42 and the fin portion 43 also serve as heat radiating fins.

Explanation of LED board 20 (mainly FIG. 9) *****
The LED substrate 20 has one top substrate 21 and four side substrates 22.
The top substrate 21 is fixed to the lower surface of the trunk portion 41.
The side substrate 22 is fixed to the side surface of the trunk portion 41.
Each substrate has three LEDs 23 (light emitting diodes).

  The top substrate 21 is a substrate that is the same as or slightly smaller than the size of the planar portion of the lower surface of the body portion 41, and is a substantially square substrate having no corners. The LEDs 23 are arranged at three corners of the top substrate 21, and power terminals for joining the DC electric wires 92 are arranged at one corner. In the center of the top substrate 21, there is an elliptical or elongated substrate hole 25 having the same size as the through hole 45.

  The top substrate 21 is disposed in a space partitioned by the lower surface of the body portion 41, the top cover 10, and the lower portions of the side covers 30.

  The side substrate 22 is a horizontally long rectangular substrate that is the same as or slightly smaller than the size of the planar portion of the side surface of the body portion 41. The side substrate 22 has three LEDs fixed in a horizontal row on the upper side, and a power supply terminal is arranged on the lower side. By arranging three LEDs in a horizontal row, the LEDs are arranged at a position closer to the overhanging portion 42 than when one or two LEDs are arranged in the horizontal direction. In this way, it is possible to reduce the dark portion in the vertical direction generated by the overhanging portion 42. In order to reduce the dark portion in the vertical direction generated by the overhanging portion 42, it is desirable to dispose at least two LEDs as close to the overhanging portion 42 as possible.

Since the LED lighting device 100 illuminates the four sides by the side substrate 22, the light distribution in the side direction is significantly improved as compared with the case of only the top substrate 21.
The side substrate 22 is disposed in a space partitioned by the side surface of the body portion 41, the side surface of the overhang portion 42, and the side cover 30.

Explanation of side cover 30 (mainly FIG. 16) *****
The side cover 30 has a rotating surface with a central angle of 90 degrees, and has a spherical outer peripheral surface.
The side cover 30 is transparent. Or it has translucency.
The side cover 30 is made of an insulating material such as polycarbonate.

  The side surfaces on both the left and right sides of the side cover 30 are flat surfaces that contact the side surfaces of the overhang portion 42 without a gap. The outer peripheral surface of the side cover 30 and the outer peripheral surface of the projecting portion 42 are continuous so as to be the same spherical surface, and the outer peripheral surfaces of the side cover 30 and the body portion 41 provide a spherical curved surface as a whole.

  There are a pair of upper engaging portions 31 on both sides of the upper portion of the side cover 30. The upper engaging portion 31 has a concave groove portion that is recessed downward so as to be fitted to the convex portion 47 of the trunk portion 41.

  There are a pair of lower engaging portions 32 on both sides of the lower portion of the side cover 30. The lower engaging portion 32 is formed by being bent from the outer peripheral surface to the inner peripheral direction so as to be caught by the lower surface at the lower end portion of the side surface of the body portion 41. The inner surface of the lower engaging portion 32 is caught by contacting the lower surface. On the outer surface of the lower engaging portion 32, there is a convex portion protruding downward in a convex shape.

Description of top cover 10 (mainly FIG. 12) *****
The top cover 10 has a hemispherical shape. Alternatively, it has a spherical shape that is less deep than the hemispherical shape. The outer periphery of the top cover 10 is circular.
The top cover 10 is transparent. Or it has translucency.
The top cover 10 is made of an insulating material such as polycarbonate.

  There are four corner fixing portions 11 corresponding to the four corner claw portions 46 on the outer peripheral edge portion of the top cover 10. The corner fixing part 11 has a wedge extending inward from the inside of the outer peripheral edge of the top cover 10.

  The wedge of the corner fixing portion 11 is fitted from below into a corner claw portion 46 that is bent outwardly into an L shape.

  Since the spherical surface at the tip of the L-shaped corner claw portion 46 increases in distance from the center line as it goes upward, the tip of the L-shaped corner claw portion 46 provides a slope.

  The wedge of the corner fixing portion 11 reaches the tip of the spherical surface (slope) of the L-shaped corner claw portion 46 while sliding on the spherical surface (slope) of the L-shaped corner claw portion 46 with the pressure from below to above. , And fitted inside the L-shaped corner claw portion 46.

  The wedges of the corner fixing portion 11 are fitted at four places at 90 ° intervals into a U-shaped wedge receiving portion formed by the corner claw portion 46 bent in an L shape and the lower surface of the body portion 41. Thereby, the top cover 10 is fixed to the trunk | drum 41 (heat radiation part 40).

  A holding portion 12 is provided at the outer peripheral edge portion between the corner fixing portions 11 of the top cover 10. The holding part 12 has an arcuate surface extending vertically upward from the inside of the outer peripheral edge of the top cover 10. The arcuate surface of the holding portion 12 is in contact with the outer peripheral surface outside the convex portion on the outer surface of the lower engaging portion 32. The holding portion 12 fixes the position of the outer surface of the lower engagement portion 32 from the bottom to the top so that the inner surface of the lower engagement portion 32 is fixed in contact with the lower surface of the body portion 41.

  In the side cover 30, the concave groove portion of the upper engaging portion 31 is fitted into the convex portion 47 at the upper portion, and the outer side of the convex portion on the outer surface of the lower engaging portion 32 is held by the holding portion 12 at the lower portion by the top cover 10. It is held from below. Thus, the side cover 30 is fixed to the heat radiating part 40 by the fitting by the corner fixing part 11 of the top cover 10 and cannot be detached from the heat radiating part 40.

  The upper and lower sides of the side cover 30 are held by the upper end portion of the body portion 41 and the top cover 10, and both sides of the side cover 30 are held by the side surfaces of the overhang portion 42.

  The outer peripheral surfaces of the top cover 10, the side cover 30, and the overhanging portion 42 are continuous, and the outer peripheral surfaces of the top cover 10, the side cover 30, and the trunk portion 41 provide a spherical curved surface as a whole.

Explanation of housing 57 (mainly FIG. 9) *****
The housing 57 houses the lighting circuit board 60. The housing 57 has a lower housing 50 and an upper housing 70.
In order to enhance the heat insulating effect on the lighting circuit board 60, the contact area between the heat radiation part 40 and the housing 57 is preferably as small as possible. For this reason, the housing is fixed only by the four fin portions 43.

Explanation of lower housing 50 (mainly FIG. 9) *****
The lower housing 50 is made of an insulating material such as polybutylene terephthalate (PBT) or plastic resin.

  The lower housing 50 has a conical, trumpet-shaped, or upper door-shaped throttle 51 that narrows downward. The outer peripheral surface of the throttle portion 51 is not in contact with the inner peripheral surface 44 of the body portion 41. Between the trunk | drum 41 and the internal peripheral surface 44, there exists a space which leads to the exterior in a 360 degree direction. The distance between the body 41 and the inner peripheral surface 44 is greater than or equal to the entire rotation surface, and there is a gap between the two. The reason is to prevent the heat of the body part 41 from the LED from being transmitted to the lower housing 50. If the body portion 41 and the inner peripheral surface 44 are not in contact with each other, the heat insulating effect is enhanced, and the influence of heat on the lighting circuit board 60 on the upper portion of the lower housing 50 can be reduced.

  The lower housing 50 has an annular upper portion in which lower cylindrical portions 53 and slide concave portions 54 are alternately formed on the upper portion of the throttle portion 51.

  The outer peripheral radius of the lower cylindrical portion 53 is larger than the radius R.

The outer peripheral radius of the slide recess 54 is a radius R, which is the same as the radius R of the inner peripheral surface of the fin portion 43.
The slide recesses 54 are arranged at 90 ° intervals corresponding to the positions of the fin portions 43 and there are four places.

  The thickness in the radial direction of the slide concave portion 54 and the lower cylinder portion 53 is substantially the same. Therefore, in the transverse cross section of the inner space of the annular upper portion of the lower housing 50, the four wide portions where the inner peripheral surface of the lower cylindrical portion 53 is deepened and the inner peripheral surface of the slide concave portion 54 protrude and are narrow. There are four narrow parts.

  An insertion piece 55 protrudes from the upper portion of the lower cylinder portion 53.

The arc length of the outer periphery of the slide recess 54 is the same as the arc length L <b> 2 of the inner peripheral surface of the fin portion 43.
The outer peripheral radius of the slide concave portion 54 is smaller than the outer peripheral radius of the lower cylinder portion 53, and the slide concave portion 54 provides a rotating surface that is more indented than the lower cylinder portions 53 on both sides.

  Therefore, the slide recess 54 can slide in the vertical direction on the inner peripheral surface of the fin portion 43 without a gap in the radial direction and without a gap in the circumferential direction.

  Since the lower cylinder part 53 exists between the fin parts 43, it does not interfere with the vertical slide of the fin parts 43.

  The lower housing 50 projects a wiring tube 52 having a cross-sectional area smaller than the area of the bottom surface of the throttle portion from the bottom surface of the lower portion of the throttle portion 51. The wiring tube 52 is for passing the DC electric wire 92 from the lighting circuit board 60. The cross-sectional outer shape of the wiring tube 52 is the same as the shape of an ellipse or a long hole of the through hole 45, and the wiring tube 52 is fitted into the through hole 45 without any gap and penetrates the through hole 45 and the substrate hole 25. Thus, the DC electric wire 92 can be wired to the lower surface of the top substrate 21 in an insulated state.

  The bottom surface of the throttle part 51 of the lower housing 50 abuts against the stopper 48 around the stopper 48 of the body part 41. The stopper 48 restricts the lower housing 50 from sliding downward, and the lower housing 50 is positioned. In a state where the bottom surface of the throttle portion 51 of the lower housing 50 is positioned by the stopper 48, there is a gap between the outer peripheral surface of the throttle portion 51 of the lower housing 50 and the inner peripheral surface 44 of the trunk portion 41. Further, the upper part of the gap communicates with the outside air, and convection with the outside air is possible. That is, the depth position of the throttle part 51 of the lower housing 50 is designed so that a gap is generated.

Explanation of upper housing 70 (mainly FIG. 9) *****
The upper housing 70 is made of an insulating material such as polybutylene terephthalate (PBT) or plastic resin.
The upper housing 70 has a cylindrical shape as a whole, but has a conical shape with a small diameter. The upper housing 70 has a hollow bolt shape.

  The upper housing 70 protrudes from the upper part the screw part 71 in which the helical thread was cut. The screw portion 71 is screwed inside the base 80.

  The upper housing 70 has an annular portion in which upper cylinder portions 73 and fin receiving recesses 74 are alternately formed.

  The outer peripheral radius of the upper cylindrical portion 73 is larger than the radius R.

The outer peripheral radius of the fin receiving recess 74 is the same as the radius R of the inner peripheral surface of the fin portion 43.
The fin receiving recesses 74 are arranged at intervals of 90 degrees in the fin portion 43 corresponding to the positions.

  The upper cylindrical portion 73 and the fin receiving recess 74 have substantially the same radial thickness. Therefore, the internal space of the annular portion of the upper housing 70 has four deep portions where the inner peripheral surface of the upper cylindrical portion 73 is recessed and widened, and four locations where the inner peripheral surface of the fin receiving recess 74 protrudes and becomes narrow. There is a narrow part.

  The insertion piece 55 protruding from the upper part of the lower cylinder part 53 is inserted into the inner peripheral surface of the upper cylinder part 73. Thus, the slide recess 54 and the fin receiving recess 74 are continuous, and the slide recess 54 and the fin receiving recess 74 are arranged on the same plane.

The length of the outer periphery of the fin receiving recess 74 is the same as the arc length L <b> 2 of the inner peripheral surface of the fin portion 43.
The outer peripheral radius of the fin receiving recess 74 is smaller than the outer peripheral radius of the upper cylindrical portion 73, and the fin receiving concave portion 74 exhibits a rotating surface that is dented more than the upper cylindrical portion 73 on both sides.
Accordingly, the fin receiving recess 74 can slide downward on the inner peripheral surface of the fin portion 43.
Since the upper cylinder part 73 exists between the fin parts 43, the slide to the top of the fin part 43 is not disturbed.

  A fin fixing portion 75 is provided at the lower portion of the upper tube portion 73. The fin fixing portion 75 has a structure in which the fixing claw 91 of the fin portion 43 is fitted. When the fin fixing portion 75 is fitted into the fixing claw 91 by sliding on the fin portion 43, it cannot slide in the reverse direction.

  As described above, the upper housing 70 is fixed to the space surrounded by the fin portions 43 by the fin portions 43.

Description of the lighting circuit board 60 (mainly FIG. 9, FIG. 11 and FIG. 13)
The lighting circuit board 60 receives an AC power supply, converts it to a high frequency, and then generates and outputs a DC current.
The lighting circuit board 60 includes a rectangular board 61 that is elongated in the vertical direction. The upper and lower portions of the substrate 61 are cut into a trapezoidal shape. The width of the upper part and the lower part of the substrate 61 is reduced so that it can enter the narrow space of the throttle part 51 and the screw part 81 of the lower housing 50, and the area of the substrate 61 is made as large as possible.

  A primary circuit 67 is provided near the upper and lower centers of the substrate 61, a secondary circuit 68 is provided above the primary circuit 67, and a secondary circuit 69 is provided below the primary circuit 67. The reason why the secondary circuit is separated in two places is that the aluminum electrolytic capacitor 62 is arranged at the top.

  The primary circuit 67 has a power supply terminal 65 and a film capacitor 63. There are power supply terminals 65 on both the left and right sides of the substrate 61 near the upper and lower centers. The power terminal 65 connects the AC wire 66 from the base 80. Next to the power terminal 65, a film capacitor 63 is attached in the horizontal direction.

  The secondary circuit 68 has an aluminum electrolytic capacitor 62. The lead wire of the aluminum electrolytic capacitor 62 is bent into an L shape and joined to the upper end portion of the substrate 61. The body of the aluminum electrolytic capacitor 62 is disposed in a space above the upper end of the substrate 61 and reaches the inside of the screw portion 71. If the height of the screw portion 71 is made higher than the height of the body of the aluminum electrolytic capacitor 62, the aluminum electrolytic capacitor 62 is insulated from the base 80 by the screw portion 71.

  The secondary circuit 69 has a coil 64. The circuit board 61 has a signal line pattern circuit that passes through the primary circuit 67 and connects the secondary circuit 68 and the secondary circuit 69.

  A constant current circuit is provided on the back surface of the substrate 61, and a DC electric wire 92 extends downward from the lower portion of the substrate 61 toward the wiring tube 52.

  The substrate 61 has tall components arranged on one side and is arranged in a radial direction with respect to the center line.

  The left and right long sides of the substrate 61 are arranged in two wide portions, and the corners of tall components arranged on one side of the substrate 61 are arranged in the other two wide portions. In this way, the narrow space is effectively used.

  Since the upper housing 70 is fixed to the space surrounded by the fin portions 43 by the fin portions 43, the lighting circuit board 60 is also disposed in the space surrounded by the insulating portions of the upper housing 70 and surrounded by the fin portions 43. become.

Relationship between “weight of heat dissipation unit / power consumption” and “LED temperature” ***
FIG. 19 is a diagram of the relationship between the weight of the heat radiation unit 40 of the LED lighting apparatus 100 according to Embodiment 1, the power consumption of the LED lighting apparatus 100, and the LED temperature.
The horizontal axis of FIG. 19 is the ratio (weight g / power W) between the weight of the heat radiation unit 40 and the power consumption.
The vertical axis in FIG. 19 represents the LED temperature (Celsius) of the LED substrate 20.

The measurement conditions are as follows.
As for the LED temperature, the higher one of the LED of the top substrate 21 and the LED of the side substrate 22 is measured.
LED temperature measures the temperature of the solder side of a cathode side.
The lighting direction is such that the base 80 is directed to the ceiling.
The LED lighting device 100 is turned on at 100V, 50/60 Hz.
The LED lighting device 100 is lit alone and measured at room temperature of 25 ° C.

The target value of LED temperature is as follows.
In order to suppress a decrease in brightness due to thermal degradation of the LED, the LED temperature in the lamp needs to be 100 ° C. or lower.

  In addition, LED lamps are usually mounted and lit by an instrument whose light emission direction is released. However, when the lamp is covered and sealed with a lamp cover such as when used outdoors or in a bathroom, the temperature conditions become more severe. . In such a case, it is desirable that the LED temperature be 95 ° C. or lower under the above measurement conditions.

  As shown in FIG. 19, when the ratio between the weight of the heat radiating unit 40 and the power consumption increases, the LED temperature decreases.

When the ratio of the weight of the heat radiating unit 40 to the power consumption is about 2.6, the LED temperature is about 102 degrees.
When the ratio of the weight of the heat radiating unit 40 to the power consumption is about 3.0, the LED temperature is about 98 degrees.
When the ratio of the weight of the heat dissipating part 40 to the power consumption is about 3.9, the LED temperature is about 94 degrees.
When the ratio of the weight of the heat dissipating unit 40 to the power consumption is about 6.0, the LED temperature is about 90 degrees.
When the ratio of the weight of the heat radiating part 40 to the power consumption is about 7.6, the LED temperature is about 88 degrees.
When the ratio of the weight of the heat radiation unit 40 to the power consumption is about 9.3, the LED temperature is about 87 degrees.

  When the ratio of the weight of the heat radiating unit 40 to the power consumption is about 6, it is possible to measure by adding an aluminum metal part without changing the appearance of the LED lighting device 100 described above. However, when the ratio of the weight of the heat radiating part 40 to the power consumption is about 6 or more, there is a change in the appearance of the LED lighting device 100, the constricted part near the base becomes thicker, and the appliance compatibility rate (hard to attach to the appliance) ) Is inferior.

  As a result, if the ratio between the weight of the heat radiation part 40 and the power consumption (weight g / power W) is 2.8 or more and 6.0 or less, the LED temperature can be reduced to 100 degrees or less and the appliance compatibility rate is reduced. It can be maintained.

  More preferably, in order to make the LED temperature 95 degrees or less, it is preferable to set the weight g / power W to 3.4 or more and 6.0 or less.

  Further, in order to reduce the weight and set the LED temperature to 95 ° C., it is preferable to set the weight g / power W to 3.4 or more and 4.0 or less.

  Furthermore, considering the case where the LED lighting device 100 is used in a sealed state, the weight g / power W is preferably set to 6.0 in order to reduce the LED temperature to 90 degrees or less.

Preferred specification example of LED lighting device 100 (mainly, FIGS. 1 and 9) ******
A suitable specification example when the LED lighting device 100 is a mini-krypton bulb is as follows.
LED lighting device 100 height H1 = about 67 mm
Maximum outer diameter L1 of the LED lighting device 100 = 34 to 36 mm
Rated power consumption of LED lighting device 100 = 6-7W
Weight of LED lighting device 100 = about 50 g
Weight of heat radiation part 40 = 18-25g
The distance between the opposite side surfaces of the body part 41 = about 24 mm
The height of the body portion 41 (height of the side surface of the body portion 41) H2 = about 13 to 15 mm The width of the side surface of the body portion 41 (excluding the overhang portion 42) L3 = about 14 to 15.5 mm
Maximum overhang length of the overhang portion 42 in the radial direction from the side surface of the body portion 41 = about 5 mm
Inner peripheral surface radius R of the fin portion 43 = about 11 mm
The outer peripheral surface arc length L2 of the fin portion 43 = the inner peripheral surface arc length L2 of the fin portion 43 = 6 to 7 mm.
Height H3 of the fin part 43 from the upper surface of the body part 41 = about 20 to 23 mm
Radial length of base of fin portion 43 = about 7 mm
Number of top substrates 21 = 1 substrate Number of LEDs on top substrate 21 = 3 Number of side substrates 22 = 4 substrates Number of LEDs on side substrate 22 = 3 Total number of LEDs = 15

The suitable composition ratio of LED lighting device 100 (especially heat dissipation part 40) is as follows.
The ratio of the weight of the heat radiation part 40 (18 to 25 g) and the weight of the LED lighting device 100 (50 g) is 36% or more and 50% or less (18/50 or more and 25/50 or less). In this embodiment, the weight of the heat radiation part 40 is preferably 23.6 g, and the ratio of the weight of the heat radiation part 40 and the LED lighting device 100 is preferably 47.2% (23.6 / 50).

  The ratio of the maximum diameter L1 (34 to 36 mm) of the LED lighting device 100 to the arc length L2 (6 to 7 mm) of the outer periphery of the overhanging portion 42 is 4.86 or more and 6.0 or less (34/7 or more 36 / 6 or less).

  The ratio between the width L3 (14 to 15.5 mm) of the side surface of the body portion 41 and the arc length L2 (6 to 7 mm) of the outer periphery of the overhanging portion 42 is 2.0 to 2.58 (14/7 to 15). .5 / 6 or less).

  The ratio of the height H1 (67 mm) of the LED lighting device 100 to the height H2 (13 to 15 mm) of the body 41 of the heat radiating unit 40 is 4.47 or more and 5.15 or less (67/15 or more and 67/13). The following).

  The ratio of the height H3 (20 to 23 mm) of the protrusion of the fin portion 43 from the upper surface of the body portion 41 to the height H2 (13 to 15 mm) of the body portion 41 of the heat radiating portion 40 is 1.33 or more and 1.77. It is below (20/15 or more and 23/13 or less).

  Since the inner peripheral surface radius of the fin portion 43 is 11 mm and the inner peripheral surface arc length L2 of the fin portion 43 is 6 to 7 mm, the central angle of the fin portion 43 is 31.26 degrees to 36.47 degrees. If the outer peripheral radius of the LED lighting device 100 (the outer peripheral radius of the upper cylindrical portion 73 of the upper housing 70 of the housing 57) at the upper end of the fin portion 43 (the constricted portion of the LED lighting device 100) is 11 mm, four fins The ratio of the total arc length (L2 × 4) of the outer periphery of the portion 43 to the outer peripheral length of the LED lighting device 100 at the tip of the fin portion 43 is about 38% (34.7% or more and 40.5% or less).

  Moreover, when the maximum outer diameter L1 of the LED lighting device 100 is 34 to 36 mm, the outer periphery of the LED lighting device 100 has a maximum outer peripheral length of 106.76 to 113.04 mm (34 × π to 36 × π mm). The ratio of the total arc length (L2 × 4, 6 × 4 to 7 × 4 = 24 to 28) and the maximum outer periphery length (106.76 to 113.04 mm) of the outer periphery of each fin portion 43 is about 25% ( 21.2% to 26.2%, and 24 / 113.04 to 28 / 106.76).

Features of the configuration of the embodiment *****
The features of this embodiment are as follows.
The heat radiation part 40 of the LED lighting device 100 has a polygonal columnar outer shape having an upper surface, a lower surface, and a plurality of side surfaces.

  The heat radiating portion 40 includes a barrel portion 41 formed with a cutout 49 that tapers from the upper surface toward the lower surface, a plurality of overhang portions 42 that project from the corner of the barrel portion 41 in the lateral direction (radial direction), And a plurality of fin portions 43 projecting upward from the corners of the portions 41.

  The LED substrate 20 has a plurality of LEDs 23 (light emitting diodes) mounted thereon and is attached to the heat dissipation unit 40.

  The inner peripheral surface of the body portion 41 is formed by a rotation surface with the center line in the vertical direction of the body portion 41 as an axis.

  The cutout 49 is a trumpet-shaped cutout protruding to the center line side of the body portion 41.

The LED lighting device 100 further includes a lighting circuit board 60 and a housing 57 that houses the lighting circuit board 60.
The housing 57 is separated from the body 41 by a plurality of fins 43 without contacting the body 41 and is fixed above the body 41.

The housing includes an upper housing 70 and a lower housing 50 attached from the lower portion of the upper housing 70 toward the body portion 41,
The lower housing 50 is disposed in the space of the cutout 49 without contacting the inner peripheral surface of the cutout 49 of the body portion 41.

The body portion 41 has a through hole 45 penetrating from the tip of the cutout 49 to the lower surface,
The lower housing 50 includes a wiring tube 52 that penetrates the through hole 45 and draws the DC electric wire 92 to the lower surface of the body portion 41.

The accommodating housing accommodates the elongated lighting circuit board 60 vertically in a cylindrical space,
In the lighting circuit board 60, a secondary circuit 68 having an aluminum electrolytic capacitor 62 is arranged on the upper side of a primary circuit 67 having a power supply terminal 65 connected to an AC power supply and a rectifying circuit for rectifying the AC, and the lower side of the primary circuit 67. A secondary circuit 68 having a coil 64 is disposed on the side.

  The body portion 41 includes, as the LED substrate 20, a top substrate 21 attached to the lower surface and a side substrate 22 attached to the side surface, and the side substrate 22 arranges LEDs in a horizontal row.

The LED illumination device 100 includes a heat radiation part 40 having a polygonal columnar outer shape having an upper surface, a lower surface, and a plurality of side surfaces, a top substrate 21 mounted with an LED (light emitting diode) and attached to the lower surface of the heat radiation part, A top cover 10 covering the top substrate 21;
The heat dissipating part 40 has a plurality of corner claw parts 46 arranged at the corners on the lower surface,
The top cover 10 has a plurality of corner fixing portions 11 that engage with the corner claw portions 46.

The LED lighting device 100 further includes:
A side substrate 22 mounted with LEDs 23 and attached to the side surface of the heat dissipation unit 40;
A side cover 30 covering the side substrate 22;
The heat radiating part 40 has a convex part 47 arranged at the upper part of the side surface,
The top cover 10 has a holding portion 12 on the outer edge,
The side cover 30 has an upper engaging portion 31 that engages with the convex portion 47 at the upper portion, and has a lower engaging portion 32 that is held by the holding portion 12 so as not to be detached from the lower end portion of the side surface.

The top cover 10 has a hemispherical shape,
The plurality of corner fixing portions 11 are formed on the outer peripheral edge of a hemispherical shape,
The holding part 12 has an arcuate outer peripheral edge part between two adjacent corner fixing parts 11,
The lower engaging portion 32 is formed so as to engage with an arcuate outer peripheral edge portion between two adjacent corner claw portions 46.

The corner fixing part 11 of the top cover 10 is fitted into the corner claw part 46 of the heat radiating part 40 from below,
By fitting the corner fixing portion 11 and the corner claw portion 46, the top cover 10 is fixed to the heat radiating portion 40, and the holding portion 12 of the top cover 10 holds the lower engagement portion 32 of the side cover 30. The side cover 30 is fixed to the heat radiating part 40.

The corner claw portion 46 of the heat radiating portion 40 has an L-shape with a spherical outer peripheral surface at the tip,
The corner fixing part 11 of the top cover 10 has a wedge fitted inside the L-shaped corner claw 46 while sliding the spherical surface of the L-shaped corner claw 46 from below to above.

The heat radiating portion 40 has a plurality of overhang portions 42 between the side covers 30.
The corner claw portion 46 of the heat radiating portion 40 is formed on the lower surface of the heat radiating portion 40 inside the outer periphery of the lower end of the overhang portion 42.
The outer peripheral surface of the top cover 10, the outer peripheral surfaces of the plurality of overhang portions 42, and the outer peripheral surfaces of the plurality of side covers 30 form a continuous spherical outer shape.

  In addition, although the case where the thermal radiation part 40 of the LED lighting apparatus 100 was a quadrangular prism was shown, it should just be a polygonal prism. However, in the case of a triangular prism, a dark part may occur depending on the light distribution angle. Further, in the case of a pentagonal prism or more, the structure becomes complicated and the number of parts increases. Therefore, a quadrangular prism is desirable.

  Moreover, the side surface of the trunk portion 41 may not be orthogonal to the upper surface and the lower surface, and may be inclined within a range of several degrees. For example, if it is desired to increase the light distribution obliquely below the side, the side surface may be inclined obliquely downward. Further, when it is desired to increase the light distribution obliquely above the side, the side surface may be inclined upward.

  The terms “upper”, “lower”, “upward” and “downward” are used for easy understanding of the configuration shown in the drawings, and mean relative position and relative direction, meaning the direction of gravity. do not do. For example, when the contents of the drawings are shown upside down, the terms “upper”, “lower”, “upward”, and “downward” have opposite meanings.

  Even if the values shown in the above embodiments vary within a range of ± 10% (preferably ± 5%, more preferably ± 2%) of each value, the same effect or similar effect as each value is exhibited.

Furthermore, the LED lighting device of the embodiment according to the present invention is:
A barrel portion having a polygonal columnar shape having an upper surface, a lower surface, and a plurality of side surfaces, with a hollow formed with a taper from the upper surface toward the lower surface, and a plurality of tensions extending laterally from the corner of the trunk portion A heat radiating portion having a protruding portion and a plurality of fin portions protruding upward from the corner of the trunk portion;
An LED (light emitting diode) is mounted, and an LED substrate attached to a heat dissipation part is provided.

  The inner peripheral surface of the body portion is formed by a rotating surface with the center line of the body portion as an axis.

  The cutout is a trumpet-shaped cutout projecting to the center side of the body portion.

The LED lighting device further includes a lighting circuit board, and a housing housing that houses the lighting circuit board,
The receiving housing is characterized in that it is fixed apart from the upper portion of the trunk portion by a plurality of fin portions without contacting the trunk portion.

The housing includes a lower housing attached from the lower part toward the trunk part,
The lower housing is characterized in that it is arranged in a cutout without contacting the cutout inner peripheral surface of the barrel.

The trunk portion has a through-hole penetrating from the leading end of the hollow to the bottom surface,
The lower housing has a wiring tube that penetrates the through hole and draws the electric wire to the lower surface of the body portion.

The storage housing stores the lighting circuit board vertically in a cylindrical space,
The lighting circuit board includes a secondary circuit having a capacitor on the upper side of a primary circuit having a power supply terminal connected to an AC power supply and a rectifying circuit for rectifying the AC, and a secondary circuit having a coil on the lower side of the primary circuit. It is arranged.

  The body portion includes, as LED substrates, a top substrate attached to a lower surface and a side substrate attached to a side surface, wherein the side substrates have LEDs arranged in a horizontal row.

  The ratio between the weight of the heat radiating part and the power consumption is 2.8 or more and 6.0 or less.

  The ratio between the outer peripheral length of the LED lighting device and the total arc length of the outer periphery of the plurality of fin portions is 25% or more and 38% or less.

The polygonal column is a square column,
The ratio between the maximum diameter L1 of the LED lighting device and the arc length L2 of the outer periphery of the overhanging portion is 4.86 or more and 6.0 or less,
The ratio between the width L3 of the side surface of the trunk portion and the arc length L2 of the outer periphery of the overhang portion is 2.0 or more and 2.58 or less,
The ratio between the height H1 of the LED lighting device and the height H2 of the body portion of the heat radiating portion is 4.47 or more and 5.15 or less,
The ratio of the height H3 of the protrusion of the fin portion from the upper surface of the body portion and the height H2 of the body portion of the heat radiating portion is 1.33 or more and 1.77 or less.

  10 top cover, 11 corner fixing part, 12 holding part, 20 LED board, 21 top board, 22 side board, 23 LED, 25 board hole, 30 side cover, 31 upper engagement part, 32 lower engagement part, 40 heat dissipation Part, 41 trunk part, 42 overhang part, 43 fin part, 44 inner peripheral surface, 45 through hole, 46 corner claw part, 47 convex part, 48 stopper, 49 hollow, 50 lower housing, 51 restricting part, 52 wiring pipe , 53 Lower cylinder part, 54 Slide recess, 55 Insertion piece, 57 Housing housing, 60 Lighting circuit board, 61 board, 62 Aluminum electrolytic capacitor, 63 Film capacitor, 64 Coil, 65 Power supply terminal, 66 AC wire, 67 Primary circuit, 68 Secondary circuit, 69 Secondary circuit, 70 Upper housing, 71 Screw part, 73 Upper tube part, 74 Fin receiving recess 75 fin fixing portion 80 mouthpiece, 91 fixed claws, 92 DC electric wire, 100 LED lighting device.

Claims (9)

A heat dissipating part formed in a direction along the center line in a state where a plurality of heat dissipating fins are arranged around the center line;
An LED (light emitting diode) disposed on the opposite side of the heat radiation portion from the center line;
A side cover fixed to the heat dissipating part in a state of covering the LED;
LED lighting device comprising: The LED is
The LED lighting device according to claim 1, wherein the LED lighting device is disposed on a side surface formed on a side opposite to the center line of the heat radiation portion. The LED is
The LED lighting device according to claim 2, wherein the LED lighting device is mounted on an LED substrate attached to the side surface. The heat dissipation part is
The LED according to any one of claims 1 to 3, wherein a housing is fixed to one end of the heat dissipating part with a gap between the LED and the inner peripheral surface facing the side surface. Lighting device. The housing is
The LED lighting device according to claim 4, wherein a DC electric wire is passed and fixed to the heat radiating fin formed on one end side of the heat radiating portion. A plurality of heat dissipating parts;
A housing housing which houses the lighting circuit and fixes one end of the plurality of heat dissipating parts;
With
The housing housing is an LED lighting device having a plurality of fixing portions for fixing the plurality of heat radiation portions on an outer periphery. The housing is cylindrical,
The LED fixing device according to claim 6, wherein there are four fixing portions at intervals of 90 degrees.   The LED lighting device according to claim 6, further comprising a trunk portion to which the other ends of the plurality of heat radiation portions are fixed. Having a base attached to the housing;
The housing includes a screw part screwed inside the base, and an annular part continuous from the screw part,
The LED lighting device according to claim 6, wherein the fixing portion is formed in the annular portion.

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