JP6467462B2 - LED lamp - Google Patents

Description

  The present invention relates to an LED lamp.

  Conventionally, high-intensity discharge lamps (HID lamps) such as mercury lamps have been used mainly for road lights and tunnel lights that illuminate the roadway.

  However, road lights and tunnel lighting are often installed in places where it is difficult to replace the lamp, and there has been a problem that the maintenance cost of the lamp replacement becomes high.

  Therefore, it has been desired to develop a long-life LED lamp as an alternative to the conventional HID lamp. LED lamps are generally considered to have a life several times longer than HID lamps.

  However, when the LED is used at a high temperature, its life is shortened.

  On the other hand, an illuminating device that can improve heat dissipation and extend the life is provided (see Patent Document 1). In this illuminating device, the airflow flowing into the duct portion 14 from the opening 10a by driving the blower fan 20 circulates along the heat radiating plate 13 and is sent out through the opening 10a.

  However, it has been difficult for the lighting device as described above to sufficiently suppress the temperature rise of the LED in road lights and tunnel lighting that require high output.

JP 2013-254576 A

  An object of this invention is to provide the LED lamp which suppresses the temperature rise of LED in view of the above-mentioned problem.

The present invention relates to an LED that emits light, a substrate on which the LED is provided on one surface, a radiator that is provided on the other surface of the substrate, and a translucent coating that covers at least one surface of the substrate and the LED. Cover, a base provided near the first side of the substrate, a fan provided near the second side of the substrate facing the first side, and at least a first of the substrate A second reflecting member that reflects light from the LED toward the two side sides and directs the light toward the space on the one surface side of the substrate, and the fan is near the second side, The gas flowing by the fan is guided from one side to the back side of the LED of the heat dissipator on the back side of the second reflecting member. and characterized in that it is a LED lamp with a gas guide surface That.

  By this invention, the LED lamp which suppresses the temperature rise of LED can be provided.

The front view of a LED lamp. The bottom view of a LED lamp. The right view of an LED lamp. The left view of an LED lamp. The partial cross section front view of a LED lamp. The partial cross section bottom view of an LED lamp. The right side sectional view of an LED lamp. The partial cross section enlarged front view which shows the rotation mechanism part of a LED lamp. The partial cross section front view which shows the flow of the air of an LED lamp. Explanatory drawing of the LED lamp of Example 2. FIG. The top view of the LED lamp of Example 2. FIG. FIG. 6 is a partially cut perspective view of the LED lamp of Example 2.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

<Overall configuration / Appearance>
1 is a front view of the LED lamp 1 laid sideways, FIG. 2 is a bottom view of the LED lamp 1 laid sideways, and FIG. 3 is a right side view of the LED lamp 1 laid sideways. FIG. 4 is a left side view of the LED lamp 1 laid sideways.

  As shown in FIGS. 1 and 2, the LED lamp 1 includes a cylindrical translucent cover 5, an end cap 71 provided at an opening 54 at one end 53 of the cover 5, and an opening 56 side at the other end 55. The base 6 is provided. In the cover 5, a substrate 3 and a radiator 4 provided with LEDs 2 that emit light are provided. The opening 54 at one end 53 of the cover 5 has a substantially cylindrical shape whose outer diameter is substantially the same as the outer diameter of the cover 5, and has an opening 76 on the surface on the cover 5 side. An end cap 71 having a closing portion 75 is connected. The closing portion 75 of the end cap 71 is provided with a plurality of vent holes 73 (see FIG. 3). On the opening 56 side of the other end 55 of the cover 5, the outer diameter is approximately the same as the outer diameter of the cover 5, and the diameter of the connecting mold 62 gradually decreases from the connecting mold 62 side to the base 6 side. A substantially frustoconical base mold 61 and a base 6 are connected in this order. One end 67 of the base mold 61 is connected so as to be rotatable around the axis of the connection mold 62 and the connection mold 62, and the other end 68 is capped by the base 6. The axis of the cover 5, the axis of the connecting mold 62, the axis of the base mold 61, and the axis of the base 6 all coincide. A plurality of vent holes 65 are also provided in the side surface portion 66 of the die mold 61 (see FIG. 4). Here, as the base 6, an E39 revolving type base is used, and the outer diameters of the cover 5, the end cap 71, and the connecting mold 62 are all about 65 mm, and the total length is about 290 mm. Thus, the outer shape of the existing metal halide lamp and the compatibility with the socket are provided. A fan 7 is stored in the end cap 71.

<Internal structure>
FIG. 5 is an assembly view (partially sectional front view) of the LED lamp 1 laid sideways, and FIG. 6 is an assembly view (partially sectional bottom view) of the LED lamp 1 laid sideways. FIG. 7 is a right side cross-sectional view of the central portion of the LED lamp 1 laid sideways.

≪LED / Board≫
As shown in FIGS. 5 and 6, the LED lamp 1 uses a COB (Chip On Board) type LED 2 in which the LED 2 is surface-mounted on a substrate 3. Here, in the LED 2, for example, a plurality of blue LED chips (not shown) are arranged in a planar shape on one surface 31 (the lower surface in FIG. 5) of the substrate 3, and the surface of the blue LED chip is a yellow phosphor. An LED emitting white light coated with (not shown) can be used. The number of blue LED chips used is selected according to the specifications of the LED lamp 1, for example, the total luminous flux, and the supply power is also determined at the same time.

  The substrate 3 is made of an appropriate material such as a metal material such as aluminum or a ceramic material. The substrate 3 is a substantially rectangular flat plate, and is arranged so that the inside of the cover 5 is separated into an upper half semi-column and a lower half semi-column at approximately the center of the cover 5. The LED 2 is mounted on one surface 31 of the substrate 3. The LED 2 is arranged in a circular shape in the central portion 35 of the one surface 31 of the substrate 3. The substrate 3 is arranged so that the base 6 is provided in the vicinity of the first side 33 of the short side, and the fan 7 is provided in the vicinity of the second side 34 facing the first side 33. The board 3 is provided with a connector 30 at one corner 36 on the first side 33 side of the one surface 31. The substrate 3 has an electrical wiring pattern (not shown) printed on one surface 31. As a result, the LED 2 mounted on the substrate 3 is electrically connected to the connector 30 by the electric wiring pattern printed on the substrate 3, and is further connected to the base by electric wiring (not shown) via the connector 30. 6 is electrically connected. The substrate 3 is provided with a heat radiating body 4 on the other side 32 (upper side in FIG. 5). The substrate 3 is closely attached and fixed with screws so that the entire surface of the other surface 32 is in surface contact with the one end surface 43 of the radiator body 41 of the radiator 4.

≪Heat radiator≫
The radiator 4 is made of a metal material such as aluminum having good thermal conductivity. The heat radiating body 4 is integrally provided with a heat radiating body main body 41 and a plurality of fins 42.

  The heat dissipating body main body 41 is a substantially rectangular plate-like body that is slightly larger than the substrate 3 that is in surface contact with the one end face 43, and the short sides (first side 45, second side 46) are substrates. Slightly longer than 3, the long sides 48 and 49 are formed to be about three times longer than the short sides (the first side 45 and the second side 46). The heat dissipating body main body 41 is directed so that the short sides (the first side 45 and the second side 46) of the substrate 3 face each other, and the substrate 3 faces the second side 46 from the center of the one end face 43. It is arranged on the side a little closer to the fan 7 on the side. The heat dissipating body main body 41 is arranged so that the second side edge 46 is spaced apart from the second side edge 34 of the substrate 3. The heat dissipating body main body 41 is formed with a U-shaped notch 47 cut into the second side 46 near the second side 34 of the substrate 3. The notch 47 functions as a vent for allowing a part of the air sucked by the fan 7 to vent into a gap between adjacent fins 42 described later.

  Each fin 42 is a substantially rectangular plate-like body, and the long sides 42 a and 42 b are along the longitudinal direction of the radiator body 41, and it is assumed that there is no notch 47 of the radiator body 41. It extends from the second side edge 46 to the first side edge 45 that faces. Each fin 42 is erected substantially vertically with respect to the heat dissipating body main body 41, with one of the long sides 42 a contacting the other end surface 44 of the heat dissipating body main body 41. The fins 42 are arranged in parallel with each other at substantially equal intervals. Note that the lengths (heights) of the short sides 42 c and 42 d of the fins 42 are individually adjusted so that the fins 42 do not contact the inner peripheral surface 51 of the cover 5.

≪Reflector≫
The radiator body 41 is provided with a base reflector 21 and a top reflector 22 that reflect light emitted from the LED 2.

  The base reflector 21 has a substantially semi-cylindrical shape in which the diameter surface 21 a and one end surface 21 b are opened, and the diameter surface 21 a is between the first side 45 of the radiator body 41 and the first side 33 of the substrate 3. The radiator body 41 is fixed with screws so as to be in contact with one end surface 43 of the radiator body 41. The base reflector 21 has the other end surface 21c in contact with the one end surface 43 of the radiator body 41 and the diameter of an end side 21d adjacent to the first side 33 of the substrate 3 in parallel. And a reflecting plate 23 having a reflecting surface 23a that reflects the light from the LED 2 toward the space on the one surface 31 side of the substrate 3. That is, the reflection plate 23 is formed in a shape in which half of the LED 2 side of the inside of the cover 5 is obliquely cut, and a contact portion with the radiator body 41 is closer to a portion close to the inner surface of the cover 5. The LED 2 is inclined so as to be close to the LED 2. In addition, a through-hole 25 through which an electrical wiring (not shown) for electrically connecting the connector 30 and the base 6 is provided in a part of the reflection plate 23. Further, the size of the base reflector 21 is adjusted so that the vertically long semicircular arc-shaped portion 21 e does not contact the inner peripheral surface 51 of the cover 5.

  The top reflector 22 has a substantially semi-cylindrical shape in which the diameter surface 22 a and one end surface 22 b are open, and the diameter surface 22 a is between the second side edge 46 of the radiator body 41 and the second side edge 34 of the substrate 3. The radiator body 41 is fixed with screws so as to be in contact with one end surface 43 of the radiator body 41. The top reflector 22 has the other end surface 22c in contact with the one end surface 43 of the radiator body 41 and the diameter of the end side 22d adjacent to the second side 34 of the substrate 3 in parallel. And a reflecting plate 24 having a reflecting surface 24a that reflects light from the LED 2 toward the space on the one surface 31 side of the substrate 3 in a substantially semi-circular shape that is slanted obliquely. That is, the reflecting plate 24 is formed in a shape in which half of the LED 2 side of the inside of the cover 5 is diagonally cut, and a contact portion with the radiator body 41 is closer to a portion closer to the inner surface of the cover 5. The LED 2 is inclined so as to be close to the LED 2. The size of the top reflector 22 is also adjusted so that the vertically long semicircular arc-shaped portion 22 e does not contact the inner peripheral surface 51 of the cover 5. The reflector 24 has a gas guide surface 24b on the back side for guiding the air sucked into the one surface 31 side of the substrate 3 by the fan 7 toward the fins 42 of the radiator 4 on the other surface 32 side of the substrate 3. Have.

≪Cover≫
The LED lamp 1 includes a substantially cylindrical cover 5 having both ends 53 and 55 that cover the substrate 3 on which the LED 2 is mounted, the radiator 4, the base reflector 21, and the top reflector 22.

  The cover 5 is made of a plastic material such as polycarbonate and is formed in a cylindrical shape having a constant diameter, and has translucency that transmits light emitted from the LED 2. The cover 5 has an inner diameter that is substantially the same as the length of the first side edge 45 and the second side edge 46 of the radiator body 41, and a pair of guide grooves 52 extending in the axial direction are opposed to the inner peripheral surface 51 in the diameter direction. It is formed in the position to do. The both ends 45a and 45b of the first side 45 of the radiator body 41 or the both ends 46a and 46b of the second side 46 of the radiator body 41 are fitted into the guide grooves 52 of the cover 5 so that the radiator body extends in the axial direction of the cover 5. By sliding the portion 41, the radiator 4, the substrate 3 on which the LED 2 is mounted, the base reflector 21, and the top reflector 22 that are fixed to the radiator main body 41 are stored in the cover 5. Can do. The cover 5 may be formed in a semi-cylindrical shape so as to cover only the LED 2 side from the heat dissipating body main body 41 and to release the rear of the heat dissipating body main body 41 (where the fins 42 are present). it can. In this case, the fin 42 can be brought into direct contact with the outside air.

≪Fan / End cap≫
As the fan 7, for example, an axial fan 7 in which air flows linearly along the axis of the electric motor 7a is used. The fan 7 is arranged such that the direction of the axis thereof is parallel to the long sides 42a and 42b of the fins 42 and the second side side 46 of the heat dissipating body main body 41 is on the extension line of the axis. The heat-dissipating body main body 41 is fixed to the end face 46 c including the second side 46 by screws. Therefore, the fan 7 is provided across the one surface 31 side and the other surface 32 side of the substrate 3.

  The end cap 71 is attached to the fan attachment ring 72 so as to cover the fan 7. As described above, the closed portion 75 of the end cap 71 is provided with a plurality of vent holes 73 (see FIG. 3).

  During rotation, the fan 7 sucks air into the LED lamp 1 from the vent hole 73 of the end cap 71 and exhausts it through the vent hole 65 of the side surface portion 66 of the base mold 61 via the heat radiating body 4 (see FIG. 3). .

≪Linked mold / Rotating guide ring / Base mold≫
FIG. 8 is an assembly view showing a longitudinal section of the rotation mechanism 8 in front view of the LED lamp 1 laid sideways. The rotation mechanism 8 is configured by combining a connection mold 62, a rotation guide ring 63, and a base mold 61. The rotation mechanism 8 is a mechanism in which a connection mold 62 connected to the radiator 4 (the fins 42 and the like) and a rotation guide ring 63 connected to the connection mold 62 rotate with respect to the base mold 61.

  More specifically, the connecting mold 62 has a substantially cylindrical shape, and a recess 62b is formed on the entire outer peripheral surface of the end 62a on the base mold 61 side.

  The rotation guide ring 63 has a ring shape, and a protruding portion 63a protruding in the radial direction is formed on the entire outer peripheral surface of the end portion 63b on the base mold 61 side. The rotation guide ring 63 is arranged in the connection mold 62 so that the axis of the rotation guide ring 63 and the axis of the connection mold 62 coincide with each other, and is fixed to the connection mold 62 with screws.

  The base mold 61 includes a substantially truncated cone body 61 c, a cylindrical connecting part 61 d that extends on the diameter-enlarged side of the body 61 c and is slidably rotatable with respect to the connecting mold 62, and the body part 61. It has a step-shaped cylindrical base attachment portion 61e that is extended to the reduced diameter side and reduced in two stages to which a base 6 (not shown) is attached. In the die mold 61, four rotation guide ring receiving members 61a are provided concentrically on the inner peripheral surface 61f of the die mold 61 at equal intervals. The rotation guide ring receiving member 61a is a plate-like body that protrudes in the axial direction from the inner peripheral surface 61f of the die mold 61, and a receiving groove 61b that receives the rotation guide ring is formed at an opposing end 61g that faces the rotation guide ring 63. Have. Each receiving groove 61b supports the rotation guide ring 63, and the groove width is slightly wider than the width of the rotation guide ring 63 including the protrusion 63a so that the rotation guide ring 63 can slide around the axis. It is concave.

  The rotation guide ring 63 is fitted in the receiving groove 61b of each rotation guide ring receiving member 61a of the base mold 61, and a part of the protrusion 63a is received by the opposing end 61g of each rotation guide ring receiving member 61a. By moving between the guide washer 64 screwed to the opposite outer end 61h radially outward of the groove 61b and protruding inward of the receiving groove 61b, and the bottom 61i of the receiving groove 61b, movement in the axial direction Is regulated.

  Thereby, the rotation guide ring 63 can be rotated around the axis without moving in the axial direction with respect to the die mold 61.

  In addition, since the recessed part 62b formed in the whole outer peripheral surface of the edge part 62a by the side of the base mold 61 is slidably fitted by the connection part 61d of the base mold 61, the connection mold 62 is slid with respect to the base mold 61. Thus, it can be rotated around the axis and can be stopped at an arbitrarily rotated position.

  Therefore, the lamp body portion including the radiator 4, the substrate 3, the LED 2, the cover 5, the fan 7, and the end cap 71 connected to the rotation guide ring 63 via the connection mold 62 is also included in the base mold 61 and the base mold 61. It is rotatable about the axis with respect to the base 6 attached to the base attaching part 61e (see FIGS. 1 to 7). Thereby, after attaching the LED lamp 1 to the socket by the base 6, the connecting mold 62 can be rotated to adjust the orientation of the main body portion, and the orientation and illumination direction of the LED 2 can be directed to an arbitrary direction such as vertically downward. .

<Air flow>
FIG. 9 is a schematic diagram showing the air flow in front view of the LED lamp 1 laid sideways.

  A portion K1 of the air sucked by the fan 7 goes straight as it is and passes through a gap surrounded by the adjacent fins 42 of the radiator 4 and the radiator body 41 (see FIG. 7). Meanwhile, the air K1 passing through the gap takes heat from the fins 42 and the heat dissipating body main body 41 of the heat dissipating body 4 heated by the heat conduction through the substrate 3 by the LED 2 that generates heat simultaneously with light emission and cools. The air K <b> 1 that has been deprived of heat from the radiator 4 and is heated is exhausted from the vent hole 65 provided in the base mold 61.

  Further, the air sucked by the fan 7 includes other air K2 that travels toward the gas guide surface 24b on the back side of the reflector 24 of the top reflector 22. When the air K2 collides with the gas guide surface 24b of the reflector 24, the direction of the airflow is changed by the guidance of the gas guide surface 24b. And the said air K2 advances toward the notch part 47 of the heat radiator main body part 41 so that the gas induction surface 24b of the said reflecting plate 24 may be followed (refer FIG. 5, 6). Then, the air K2 that has passed through the notch 47 of the radiator body 41 enters the gap surrounded by the fins 42 adjacent to the radiator 4 and the radiator body 41 from diagonally below in the figure, Then, it passes between the radiator main body 41 and the cover 5 while vibrating. When the air K2 passes, the air K2 takes heat from the fins 42 and the heat dissipating body main body 41 of the heat dissipating body 4 and cools it, like the part K1 of the air. The air K <b> 2 that has been deprived of heat from the radiator 4 and is heated is exhausted from a vent hole 65 provided in the die mold 61. Here, the air K2 passes between the radiator body 41 and the cover 5 while vibrating. For this reason, the temperature distribution (temperature difference) between the radiator main body 41 side and the cover 5 side of each fin 42 is reduced by the passage of the air K2. As a result, the temperature distribution of each fin 42 is made uniform, and the cooling efficiency is increased.

The LED lamp 1 which suppresses the temperature rise of LED2 by the above structure and operation | movement can be provided.
More specifically, the LED lamp 1 includes an LED 2 that emits light, a substrate 3 on which the LED 2 is provided on one surface 31, a radiator 4 that is provided on the other surface 32 of the substrate 3, and at least one surface of the substrate 3. In the vicinity of the second side 34 of the substrate 3 facing the first side 33 and the translucent cover 5 covering the LED 31 and the LED 2, the base 6 provided in the vicinity of the first side 33 of the substrate 3. And a fan 7 provided in the apparatus.

  For this reason, on the opposite side of the fan 7 where the substrate 3 and the heat radiating body 4 are provided, there is no major obstacle to air suction, and the resistance of the air sucked by the fan 7 is not large. As a result, the fan 7 can easily suck in a large amount of air, can efficiently cool the LED 2 mounted on the substrate 3, and can suppress an increase in the temperature of the LED 2.

  The LED lamp 1 includes a rotation mechanism 8 that enables at least the substrate 3 to rotate with respect to the base 6 around an axis parallel to the insertion direction of the base 6.

  For example, when the LED lamp 1 is attached by screwing the base 6 into a socket such as a road lamp, the direction of the LED 2 mounted on the board 3 may not be in the direction that accurately illuminates the road. However, since the LED lamp 1 includes a rotation mechanism 8 that enables at least the substrate 3 to rotate with respect to the base 6, the LED 2 mounted on the substrate 3 can be accurately positioned on the road on the spot where the LED lamp 1 is mounted. It can be adjusted to point in the direction of illumination.

  The LED lamp 1 reflects the light from the LED 2 directed toward the first side 33 of the substrate 3 and directs the reflector 23 of the base reflector 21 toward the space on the one surface 31 side of the substrate 3 and the second of the substrate 3. A reflection plate 24 of the top reflector 22 is provided that reflects light from the LED 2 toward the side 34 and directs it toward the space on the one surface 31 side of the substrate 3.

  Thereby, the light emitted from the LED 2 can be concentrated in the spatial direction on the one surface 31 side of the substrate 3, and no light is emitted on the extension line connecting the LED 2 and the reflecting plate 23 or the reflecting plate 24. For this reason, the LED lamp 1 is suitable for lighting that wants to concentrate the radiation of light on a specific spatial direction, that is, the road surface, such as a road lamp. Even if the line of sight is directed in the direction of illumination from a place where the hand is separated, there is an advantage that light from the illumination can be prevented from entering the eyes.

  In the LED lamp 1, the fan 7 is provided in the vicinity of the second side 34 of the substrate 3 so as to straddle the one surface 31 side and the other surface 32 side of the substrate 3, and on the back side of the reflector 24 of the top reflector 22 7 is provided with a gas guiding surface 24b for guiding the gas sent to the one surface 31 side of the substrate 3 toward the back surface portion of the LED 2 of the radiator 4.

  Thus, after being sucked in by the fan 7, it is guided by the gas guide surface 24 b on the back side of the reflector 24, and proceeds to the gap surrounded by the fins 42 adjacent to the radiator 4 and the radiator body 41. Thereafter, the air K2 passes between the radiator body 41 and the cover 5 while swinging up and down. For this reason, each fin 42 is not only cooled by the air K2, but also promotes equalization of the temperature distribution between the radiator body 41 side and the cover 5 side of each fin 42. Thereby, the cooling efficiency by each fin 42 improves, and in connection with this, cooling of LED2 is further accelerated | stimulated and it can suppress the temperature rise of LED2. In particular, since the fins 42 are arranged perpendicularly to the substrate 3 and arranged in parallel to each other, efficient cooling can be realized without hindering the above-described vertical shaking of the air K2.

  Further, when viewed from the side, the air K1 and K2 sent to both the front side and the back side of the substrate 3 by the fan 7 provided so as to straddle the front and back sides of the substrate 3 are all fins on the back side of the substrate 3 through the notch portions 47. To 42. As a result, the outside air can be maximally taken in and sent out to the fins 42 with restrictions in size and shape, and cooling can be performed efficiently.

  The LED lamp 1 has a configuration in which the heat radiating body 4 is long in the direction from the fan 7 to the base 6 and a plurality of fins 42 as plate-like portions that are substantially perpendicular to the substrate 3 are arranged in parallel with each other.

The radiator 4 having the above-described configuration has a large surface area in contact with the air K1 and K2 sent by the fan 7, and the air K1 and K2 can smoothly flow, so that the cooling efficiency is good. Since the LED lamp 1 is equipped with such a radiator 4 with good cooling efficiency, the temperature rise of the LED 2 can be suppressed.
Since the LED lamp 1 is actively cooled using the fan 7, it can be used as a lamp for a hermetic lighting fixture used at a gas station or the like, for example.

  FIG. 10A is a front view of the LED lamp 101 of Example 2 laid down sideways, and FIG. 10B is a bottom view of the LED lamp 101 of Example 2 laid down sideways. These are the top views of the LED lamp 101 of Example 2 laid down sideways, and FIG. 12 is the perspective view which cut | disconnects and shows the right side of the LED lamp 101 of Example 2 laid down sideways.

  Hereinafter, the difference between the LED lamp 101 of the second embodiment and the LED lamp 1 of the first embodiment will be described, and the description of the same points as the LED lamp 1 of the first embodiment will be omitted.

  As described above, as shown in FIGS. 5 and 6, the LED lamp 1 according to the first embodiment includes the radiator 4 including the radiator main body 41 and the plurality of fins 42, and the base reflector 21. And the top reflector 22 are formed of separate members. The base reflector 21 and the top reflector 22 are fixed to the radiator body 41 of the radiator 4 with screws.

  In contrast, the LED lamp 101 according to the second embodiment includes the radiator 4 (see FIG. 5), the base reflector 21 (see FIG. 5), and the top reflector 22 (see FIG. 5) in the LED lamp 1 according to the first embodiment. The LED lamp 1 is different from the LED lamp 1 of the first embodiment in that the body 104 is integrally formed. That is, the body 104 includes a body main body 141 (see FIG. 10) corresponding to the radiator main body 41 (see FIG. 5) and a base reflector 121 (see FIG. 10) corresponding to the base reflector 21 (see FIG. 5). And a top reflector portion 122 (see FIG. 10) corresponding to the top reflector 22 (see FIG. 5) and a plurality of fins 142 (see FIG. 10) are integrally provided. In addition, the method of integral molding may be by cutting or die cutting.

  The body 104 is a substantially curved plate 141a in which a body main body portion 141, a base reflector portion 121, and a top reflector portion 122 are formed by bending a substantially oval plate-like body so as to form a part of a virtual spherical surface. Is formed. The portion without the fin 142 on the back surface side of the substantially curved plate 141a functions as a gas guiding surface 124b for guiding gas.

  The body main body 141 is formed in a flat circular area formed in the center of the substantially curved plate 141a. In the body main body 141, the substrate 103 on which the LEDs 102 are surface-mounted is fixed by screws at the center of the concave surface 141c of the substantially curved plate 141a.

  The base reflector part 121 and the top reflector part 122 are formed on both sides in the longitudinal direction of the substantially curved plate 141a and adjacent to the body main body part 141, respectively.

The body 104 has a plurality of fins 142 provided on the convex surface 141b of the substantially curved plate 141a so as to stand on the substantially curved plate 141a.
Each fin 142 is a plate-like body, extends substantially along the longitudinal direction of the curved plate 141a, is substantially perpendicular to the body main body 141, and is arranged at substantially equal intervals in parallel to each other.

  The body 104 is inserted into the cylindrical cover 105 and is arranged so that the direction in which each fin 142 extends is parallel to the center line direction of the cover 105. Therefore, each fin 142 is set so that the length in the extending direction is substantially the same as the length of the cover 105. Further, the body main body portion 141 is arranged near the center line of the cover 105, and the upper and lower end sides of the fins 142 are brought close to the inner peripheral surface 151 of the cover 105 in the arrangement state. Yes. Therefore, the vertical width of each fin 142 is adjusted individually and for each place along the extending direction.

  With the above configuration and operation, the body main body portion 141, the base reflector portion 121, and the top reflector portion 122 are formed by an integral substantially curved plate 141a that does not have a discontinuous bent portion. For this reason, the air sucked by the fan 107 passes along the convex surface side 141b of the substantially curved plate 141a between the plurality of fins 142 provided upright on the convex surface side 141b of the substantially curved plate 141a. It can pass smoothly with little itchiness and can be cooled efficiently.

  Further, the base reflector portion 121 and the top reflector portion 122 are integrated with the body main body portion 141. Therefore, the base reflector part 121 and the top reflector part 122 can positively exhibit the function as a heat radiator like the body main body part 141, and the cooling efficiency is improved.

In the correspondence between the present invention and the embodiment,
The rotating means corresponds to the rotating mechanism 8,
Similarly, the first reflecting member corresponds to the base reflector 21 and the base reflector Hisada 121,
The second reflecting member corresponds to the top reflector 22 and the top reflector Hisada 122,
The plate-like portion corresponds to the fins 42 and 142,
The present invention is not limited to this embodiment, and can be various other embodiments.

  The present invention can be used in the lighting industry using LEDs.

1 ... LED lamp 2 ... LED
DESCRIPTION OF SYMBOLS 3 ... Board | substrate 4 ... Radiator 5 ... Cover 6 ... Base 7 ... Fan 8 ... Rotating mechanism 21 ... Base reflector 22 ... Top reflector 24b, 124b ... Gas induction surface 41 ... Radiator body part 42 ... Fin 121 ... Base reflector part 122 ... Top reflector

Claims (4)

An LED that emits light;
A substrate provided with the LED on one side;
A radiator provided on the other surface of the substrate;
A translucent cover that covers at least one surface of the substrate and the LED;
A base provided near the first side of the substrate;
A fan provided in the vicinity of the second side of the substrate facing the first side;
A second reflecting member that reflects at least light from the LED toward the second side of the substrate and directs it toward the space on one side of the substrate;
Equipped with a,
The fan is provided in the vicinity of the second side and straddling one side and the other side of the substrate,
The LED lamp provided with the gas induction surface which guides the gas which flows with the fan from the said one surface side toward the back surface part of the said LED of the said heat sink on the back side of the said 2nd reflection member . The LED lamp according to claim 1, further comprising a rotating unit that allows at least the substrate to rotate with respect to the base, with an axis parallel to the insertion direction of the base as a rotation axis. The first side to reflect light from the LED towards the side, the first LED lamp of claim 1 or 2, wherein with a reflective member of directing the space one surface of the substrate of the substrate. The heat radiator has a configuration in which a plurality of plate-like portions that are long from the fan toward the base and are substantially perpendicular to the substrate are arranged in parallel to face each other.
The LED lamp in any one of Claim 1 to 3 .

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