KR20200017390A - LED lamp - Google Patents

Abstract

 It provides an LED lamp that suppresses the temperature rise of the LED. The LED lamp 1 which emits light to the LED lamp 1, the board | substrate 3 in which the said LED 2 was provided in one side 31, and the heat radiator provided in the other side 32 of the said board | substrate 3. (4), a transparent cover (5) covering at least one side (31) of the substrate (3) and the LED (2), and a nipple provided near the first side (33) of the substrate (3). The fan 6 provided in the vicinity of the 2nd side edge 34 of the said board | substrate 3 used as the surface of the metal 6 and the said 1st side edge 33 was provided.

Description

LED lamp

This invention relates to an LED lamp.

Conventionally, high-brightness discharge lamps (HID lamps), such as a mercury lamp, are mainly used for the road light and tunnel lighting which illuminate a roadway.

However, road lights and tunnel lights are often installed in places where lamp replacement is difficult, and there is a problem that maintenance costs for lamp replacement are expensive.

Therefore, the development of a long lifetime LED lamp was desired as a replacement of the conventional HID lamp. LED lamps generally have a lifetime several times longer than HID lamps.

However, LEDs have a problem that their lifetime is shortened when they are used at high temperatures.

On the other hand, the lighting apparatus which can improve heat dissipation and can lengthen lifetime is provided (patent document 1, reference). In this lighting apparatus, the airflow which flowed into the duct part 14 from the opening 10a by the drive of the blower fan 20 flows along the heat sink 13 and is sent out through the opening 10a. .

However, it is difficult for the above lighting apparatus to fully suppress the temperature rise of LED in the road light and tunnel lighting which require high output.

Japanese Patent Publication No. 2013-254576

This invention is made | formed in view of the above-mentioned problem, and an object of this invention is to provide the LED lamp which suppresses the temperature rise of LED.

This invention is a LED which radiates light, the board | substrate with which the said LED was provided in one side, the radiator installed in the other side of the said board | substrate, the transparent cover which coat | covers at least one side of the said board | substrate, and the said LED, and the said board | substrate It is an LED lamp provided with the clasp provided in the vicinity of the 1st side of the side, and the fan provided in the vicinity of the 2nd side of the said board | substrate which becomes the surface facing the said 1st side.

This invention can provide the LED lamp which suppresses the temperature rise of LED.

1 is a front view of an LED lamp.
2 is a bottom view of the LED lamp.
3 is a right side view of the LED lamp.
4 is a left side view of the LED lamp.
5 is a partial cross-sectional front view of the LED lamp.
6 is a partial cross-sectional bottom view of an LED lamp.
7 is a right side cross-sectional view of the LED lamp.
8 is a partial cross-sectional enlarged front view showing a rotating mechanism portion of the LED lamp.
9 is a partial cross-sectional front view showing the flow of air in the LED lamp.
10 is an explanatory diagram of an LED lamp of Example 2. FIG.
11 is a plan view of the LED lamp of the second embodiment.
12 is a partially cutaway perspective view of the LED lamp of Example 2. FIG.

EMBODIMENT OF THE INVENTION Hereinafter, one Embodiment of this invention is described with drawing.

    << Example 1 >>

    <Whole structure / appearance>

1 is a front view of the LED lamp 1 lying sideways, FIG. 2 is a bottom view of the LED lamp 1 lying sideways, FIG. 3 is a right side view of the LED lamp 1 lying sideways, and FIG. 4 is The left side view of the LED lamp 1 lying sideways.

As shown in FIG. 1 and FIG. 2, the LED lamp 1 has an end cap provided in a cylindrical translucent cover 5 and an opening 54 of one end 53 of the cover 5. The cap 71 and the clasp 6 provided in the opening 56 side of the other end 55 are provided. In the cover 5, the board | substrate 3 in which the LED 2 which radiates light, and the heat radiator 4 are provided. In the opening 54 of the one end 53 of the cover 5, the outer diameter is substantially cylindrical with the same size as the outer diameter of the cover 5, and has an opening 76 on the surface on the cover 5 side. The end cap 71 which has the closed part 75 is connected to the surface on the opposite side to 5). The vent hole 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 substantially the same size as the outer diameter of the cover 5, and the clasp 6 is formed from the connecting mold 62 and the connecting mold 62 side. The clasp mold 61 and the clasp 6 of the substantially truncated conical shape which are gradually reduced in diameter) are connected in this order. In the clasp mold 61, one end 67 is rotatably connected around the axis of the connecting mold 62 and the connecting mold 62, and the other end 68 is capped by the clasp 6. It is. The shaft center of the cover 5, the shaft center of the connection mold 62, the shaft center of the clasp mold 61, and the shaft center of the clasp 6 all correspond. Moreover, the some vent hole 65 is also provided in the side part 66 of the clasp mold 61 (refer FIG. 4,). Here, the clasp 6 uses the E39 turn type clasp, and the outer diameters of the cover 5, the end cap 71, and the connection mold 62 are all about 65 mm, and the whole The length is about 290 mm. This makes it compatible with existing metal halide lamps, their appearance, and sockets. In the end cap 71, a fan 7 is stored.

    <Internal structure>

Fig. 5 is an assembly view (partial cross-sectional front view) by the front side of the LED lamp 1 lying sideways, and Fig. 6 is an assembly view (partial cross-sectional bottom view) by the bottom side of the LED lamp 1 lying sideways. 7 is a right side cross-sectional view of the central portion of the LED lamp 1 lying on its side.

     ≪LED / substrate≫

As shown in FIG. 5 and FIG. 6, as the LED lamp 1, the LED 2 of the COB (Chip On Board) system in which the LED 2 is mounted on the board | substrate 3 is used. Here, in the LED 2, for example, a plurality of blue LED chips (not shown) are arranged in a planar shape on one side 31 (the lower side in FIG. 5) of the substrate 3, The LED which emits white light which coat | covered the surface of the said blue LED chip with the yellow fluorescent substance (not shown) can be used. In addition, the number of uses of the said blue LED chip is selected according to the specification of the LED lamp 1, for example, the total luminous flux, etc., and supply power is also determined similarly.

As the board | substrate 3, suitable materials, such as metal materials, such as aluminum, or a ceramic material, are used. The board | substrate 3 is a substantially rectangular flat plate, and is arrange | positioned so that the inside of the cover 5 may be divided into the semi-circle of the upper half and the semi-circle of the lower half at the substantially 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 on the central portion 35 of one surface 31 of the substrate 3. In the board | substrate 3, the clasp 6 is provided in the vicinity of the 1st side 33 of a short side, and the fan (in the vicinity of the 2nd side 34 which becomes a facing surface with the 1st side 33 is a fan ( 7) is arranged to be installed. In the board | substrate 3, the connector 30 is provided in the one corner part 36 of the 1st side 33 of the one side 31. As shown in FIG. In the substrate 3, an electrical wiring pattern (not shown) is printed on one surface 31. Thereby, the LED 2 mounted on the board | substrate 3 is electrically connected with the connector 30 by the said electric wiring pattern printed on the board | substrate 3, and also the electric wiring through the said connector 30. (Not shown) is electrically connected to the clasp 6. As for the board | substrate 3, the heat sink 4 is provided in the other surface 32 (upper surface in FIG. 5). The board | substrate 3 is closely_contact | adhered so that the whole surface of the other surface 32 may be in surface contact with the one end surface 43 of the heat sink body part 41 of the heat sink 4, and it is being fixed by screwing.

     `` The radiator ''

As the heat sink 4, a metal material such as aluminum having good thermal conductivity is used. The heat radiator 4 is integrally provided with the heat radiator main body 41 and the some fin 42.

The heat sink body part 41 is a substantially rectangular plate-shaped member, which is larger than the substrate 3 that is in surface contact with one end face 43, and has a short side (the first side 45 and the first side). The two side edges 46 are slightly longer than the substrate 3, and the long sides 48 and 49 are formed to be about three times as long as the short sides (the first side edge 45 and the second side edge 46). . The heat sink body part 41 is oriented so that the short sides (the first side 45 and the second side 46) of the substrate 3 and each other face each other, and the substrate 3 faces one end. It is arrange | positioned at the side just a little closer to the fan 7 which is the 2nd side edge 46 side rather than the center of (43). The heat sink body part 41 is arrange | positioned so that the 2nd side edge 46 may leave a predetermined space | interval between the 2nd side edge 34 of the board | substrate 3. And the radiator main-body part 41 is provided with the U-shaped notch part 47 cut | disconnected to the 2nd side edge 46 near the 2nd side edge 34 of the board | substrate 3, and is formed. . In addition, the notch part 47 functions as a vent which makes a part of air which the fan 7 sucked in into the clearance gap between the adjacent pins 42 mentioned later.

Each fin 42 is a substantially rectangular plate-like body, and the long sides 42a and 42b are along the long direction of the heat sink body portion 41, and the notch portion (of the heat sink body portion 41) ( 47) it extends from the 2nd side 46 to the 1st side 45 which becomes a facing surface. And each fin 42 has one long side 42b of the long side abutting the other end surface 44 of the heat sink body portion 41, and is placed substantially perpendicular to the heat sink body portion 41. ) Each pin 42 is arranged in substantially equal intervals in parallel with each other. In addition, the length (height) of the short sides 42c and 42d of each pin 42 is adjusted individually so that each pin 42 may or may not abut against the inner circumferential surface 51 of the cover 5. It is.

     ≪Reflector≫

The heat sink main body 41 is provided with a base reflector 21 and a top reflector 22 for reflecting light emitted from the LED 2.

The base reflector 21 has a substantially semi-cylindrical shape in which the diameter surface 21a and one end surface 21b open, and the diameter surface 21a is the first side 45 of the heat sink body part 41 and the substrate. It is fixed by screw so that the one end surface 43 of the radiator main-body part 41 may contact with the 1st side 33 of (3). The base reflector 21 fits the other end surface 21c with the one end surface 43 of the radiator main body part 41, and short side adjacent to the 1st side 33 of the board | substrate 3 in parallel. (Iii) A diameter of 21 d is a vertically long, semi-circular arc shape inclined obliquely to the outside of the clasp 6 side, and the light from the LED 2 is directed to one side of the substrate 3 ( It has the reflecting plate 23 which has the reflecting surface 23a which reflects toward the space on the 31 side. That is, the reflecting plate 23 is formed in the shape which cut | disconnects the half of the LED2 side in an inside of the cover 5 at an oblique round, and radiates a main body part in the vicinity of the inner surface of the cover 5; The contact part with 41 is inclined arrange | positioned so that it may be close to LED2. In addition, a part of the reflecting plate 23 is provided with a through hole 25 through which an electrical wiring (not shown) for electrically connecting the connector 30 and the clasp 6 is provided. In addition, the base reflector 21 is size-adjusted so that the longitudinally long arc-shaped arc part 21e does not contact the inner peripheral surface 51 of the cover 5.

The top reflector 22 is a substantially semi-cylindrical shape in which the diameter surface 22a and one end surface 22b open, and the diameter surface 22a has the 2nd side edge 46 of the heat sink body part 41, and a board | substrate. It is fixed by screw so that it may abut on the one end surface 43 of the radiator main-body part 41 between the 2nd side edge 34 of (3). The top reflector 22 makes the other end face 22c abut the one end surface 43 of the radiator main body portion 41, and also has a short side adjacent to the second side 34 of the substrate 3 in parallel ( Iii) 22d is a diameter, is a vertically long, semi-circular arc shape inclined obliquely to the outside of the fan 7 side, and the light from the LED 2 is directed to one side 31 of the substrate 3; It has the reflecting plate 24 which has the reflecting surface 24a which reflects toward the space of the side. That is, the reflecting plate 24 is formed in a shape such that the half of the side of the LED 2 in the inside of the cover 5 is rounded obliquely, and the radiator main body part is in the vicinity of the inner surface of the cover 5. The contact part with 41 is inclined arrange | positioned so that it may be close to LED2. In addition, the top reflector 22 is also adjusted in size so that the vertically long arc-shaped arc part 22e does not contact the inner circumferential surface 51 of the cover 5. Moreover, the reflecting plate 24 is a heat radiator on the other side 32 side of the board | substrate 3 for the air sucked in the back side to the one side 31 side of the board | substrate 3 by the fan 7 ( It has the gas guide surface 24b which guides toward the fin 42 of 4).

     ≪Cover≫

The LED lamp 1 is provided with openings at both ends 53 and 55 covering the substrate 3 on which the above-described LED 2 is mounted, the heat sink 4, the base reflector 21, and the top reflector 22. A substantially cylindrical cover 5 is provided.

The cover 5 is formed of a plastic material such as polycarbonate and has a cylindrical shape with a constant diameter, and has a light transmitting property for transmitting the light emitted by the LED 2. The cover 5 has a pair of guide grooves 52 whose inner diameter is substantially the same as the lengths of the first side 45 and the second side 46 of the heat dissipating body 41. ) Is formed at positions facing each other in the radial direction of the inner circumferential surface 51. Both ends 45a, 45b of the first side 45 of the heat sink body part 41, or both ends 46a, 46b of the second side 46 of the cover 5 are fitted into both guide grooves 52 of the cover 5. LEDs 2 fixed to the radiator 4 and the radiator body 41 by sliding the radiator body 41 in the axial direction of the cover 5. ), The base plate 3, the base reflector 21, and the top reflector 22 can be stored in the cover 5. In addition, the cover 5 is formed in a semi-cylindrical shape, and covers only the LED 2 side from the heat sink body part 41, and the back (fin 42) of the heat sink body part 41 exists. It can also be configured to release. In this case, the pin 42 can be brought into direct contact with the outside air.

     ≪Fan (fan) / end cap (end-cap) ≫

The fan 7 uses the axial flow fan 7 which air flows linearly along the axis of the electric motor 7a, for example. The fan 7 is arrange | positioned so that the direction of the axis may be parallel to the long sides 42a and 42b of each fin 42, and the 2nd side 46 of the heat sink body part 41 may come on the extension line of the axis | shaft. The screw is fixed to the end face 46c including the second side edge 46 of the heat sink body part 41 via a fan attachment ring 72. For this reason, the fan 7 is provided over one side 31 side and the other side 32 side of the board | substrate 3.

The end cap 71 covers the fan 7 and is attached to the fan attachment ring 72. As described above, a plurality of vent holes 73 are provided in the closed portion 75 of the end cap 71 (refer to FIG. 3, reference).

The fan 7 sucks air into the LED lamp 1 from the vent hole 73 of the end cap 71 at the time of rotation, and the side portion 66 of the clasp mold 61 through the heat sink 4. Exhaust gas from the vent hole 65 of FIG.

     ≪Connection mold / rotation guide ring / clasp mold≫

FIG. 8: is an assembly view which shows the longitudinal cross section of the rotating mechanism 8 by the front view of the LED lamp 1 lying sideways. The rotation mechanism 8 is comprised by the coupling mold 62, the rotation guide ring 63, and the clasp mold 61 combined. The rotation mechanism 8 has the coupling mold 62 connected to the radiator 4 (other than the pin 42), and the rotation guide ring 63 connected to the coupling mold 62 to the clasp mold 61. It is a mechanism that rotates with respect.

In detail, the connection mold 62 is substantially cylindrical, and the recessed part 62b is formed in the whole outer peripheral surface of the edge part 62a by the clasp mold 61 side.

The rotation guide ring 63 is ring-shaped, and the protrusion part 63a which protrudes in the radial direction is formed in the all outer peripheral surface of the edge part 63b by the clasp 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 by screwing. It is.

The clasp mold 61 extends in the substantially truncated cylindrical body part 61c and the enlarged diameter side of the fuselage part 61c, and is slid and rotated with respect to the connection mold 62. FIG. Stair-shaped cylindrical clasps reduced in two stages, which are protruded on the shaft diameter side of the fuselage portion, and the clasp 6d (not shown) is mounted as possible as possible. It has an attachment part 61e. In the clasp mold 61, four rotation guide ring male members 61a are provided in the inner peripheral surface 61f of the clasp mold 61 at equal intervals in concentric circles. The rotation guide ring male member 61a is a plate-shaped body which protrudes in the axial direction from the inner circumferential surface 61f of the clasp mold 61, and is rotated at an opposing end portion 61g opposite the rotation guide ring 63. It has a receiving groove (receiving groove) (61b). Each receiving groove 61b supports the rotation guide ring 63 and has a groove width whose projection width 63 includes the protrusion 63a so that the rotation guide ring 63 can be slid to the shaft rotation. It becomes concave state slightly wider than the width of).

The rotary guide ring 63 is inserted into the receiving groove 61b of each rotary guide ring male member 61a of the clasp mold 61, and a part of the projection 63a is rotated by each rotary guide ring male member 61a. A guide washer 64 which is screwed to the opposite outer end 61h of the radially outer side than the receiving groove 61b and protrudes inward of the receiving groove 61b at the opposite end 61g of the The movement in the axial direction is regulated by sandwiching between the bottom portions 61i of 61b.

Thereby, the rotation guide ring 63 is rotatable about the shaft center, without moving to the clasp mold 61 in the axial center direction.

Moreover, in the connection mold 62, the recessed part 62b formed in the whole outer peripheral surface of the edge part 62a by the clasp mold 61 side is slidably inserted into the connection part 61d of the clasp mold 61, and is slidably inserted. As a result, the clasp mold 61 can be rotated around the center of the shaft and can be stopped at an arbitrarily rotated position.

Accordingly, the heat sink 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 through the connecting mold 62 are removed. The lamp body part which has the branch is also rotatable about an axis center with respect to the clasp 6 attached to the clasp mold 61 and the clasp attachment part 61e of the clasp mold 61 (FIGS. 1-7). , Reference). Thereby, after installing the LED lamp 1 to the socket by the clasp 6, the direction of a main body part can be adjusted by rotating the connection mold 62, and the direction and illumination direction of the LED 2 are vertically downward. Can be oriented in any direction, such as.

    <Flow of air>

FIG. 9: is a schematic diagram which shows the flow of air by the front view of the LED lamp 1 lying sideways.

A part of the air K1 sucked by the fan 7 passes straight through and passes through a gap surrounded by each of the adjacent fins 42 and the heat sink body portion 41 of the heat sink 4 (see FIG. 7). . In the meantime, the air K1 passing through the gap is each fin 42 and the heat sink body portion 41 of the heat sink 4 heated by heat conduction through the substrate 3 by the LED 2 that generates heat simultaneously with light emission. Take away heat and cool). The air K1 which has taken heat away from the heat sink 4 and becomes hot is exhausted from the vent hole 65 provided in the clasp mold 61.

Moreover, in the air sucked by the fan 7, there is another air K2 traveling toward the gas guide surface 24b on the back side of the reflector 24 of the top reflector 22. When the said air K2 collides with the gas guide surface 24b of the reflecting plate 24, the direction of airflow will change by guidance by the gas guide surface 24b. And the said air K2 advances toward the notch part 47 of the heat sink body part 41 so that it may follow the gas guide surface 24b of the said reflecting plate 24 (refer FIG. 5, 6,). . And the air K2 which passed the notch part 47 of the heat sink body part 41 is obliquely shown in the figure by the clearance gap which is surrounded by each adjacent fin 42 and the heat sink body part 41 of the heat sink 4. It enters from below and passes through it, vibrating between the heat sink body part 41 and the cover 5 after that. And the said air K2 takes heat away from each fin 42 and the heat sink body part 41 of the heat sink 4 similarly to the part K1 of air, and cools it as it passes. And the said air K2 which took heat from the heat sink 4 and became hot is exhausted from the vent hole 65 provided in the clasp mold 61. As shown in FIG. In addition, the said air K2 has passed through the vibration body main body 41 and the cover 5 here, 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 becomes small by passage of the said air K2. As a result, the fins 42 have a uniform temperature distribution, thereby increasing the cooling efficiency.

According to the above structure and operation, the LED lamp 1 which suppresses the temperature rise of the LED 2 can be provided.

In detail, the LED lamp 1 includes the LED 2 emitting light, the substrate 3 on which the LED 2 is disposed on one side 31, and the heat radiation provided on the other side 32 of the substrate 3. A sieve 4, a translucent cover 5 covering at least one side 31 of the substrate 3 and the LED 2, and a clasp provided near the first side 33 of the substrate 3 ( 6) and the fan 7 provided in the vicinity of the 2nd side 34 of the board | substrate 3 used as the facing surface of the 1st side 33 is provided.

For this reason, on the opposite side where the board | substrate 3 and the heat sink 4 of the fan 7 are provided, there is no big obstacle in the inhalation of air, and the resistance of the air which the fan 7 inhales is not large. Thereby, the fan 7 can inhale a large amount of air easily, and can efficiently cool the LED 2 mounted on the board | substrate 3, and can suppress the temperature rise of the LED2.

The LED lamp 1 is equipped with the rotation mechanism 8 which enables the board | substrate 3 to rotate with respect to the clasp 6 at least about the axis parallel to the insertion direction of the clasp 6.

For example, in the case where the LED lamp 1 is mounted by screwing the clasp 6 into a socket such as a road lamp, the direction of the LED 2 mounted on the substrate 3 accurately reflects the road. There is a thing which does not face. However, since the LED lamp 1 is equipped with the rotation mechanism 8 which makes the board | substrate 3 rotate with respect to the clasp 6 at least, it mounted in the board | substrate 3 on the place which mounted it. The direction of the LED 2 can be adjusted to face the direction of accurately illuminating the road.

The LED lamp 1 reflects light from the LED 2 toward the first side 33 side of the substrate 3, and the base reflector directs the space on the one side 31 side of the substrate 3. Reflecting light from the LED 2 toward the second side edge 34 side of the substrate 3 and the reflecting plate 23 of the substrate 21 is directed to the space on one side 31 side of the substrate 3. The reflector 24 of the top reflector 22 is provided.

As a result, the light emitted by the LED 2 can be concentrated in the spatial direction on the one side 31 side of the substrate 3, and an extension line for binding the LED 2 to the reflector 23 or the reflector 24 is provided. Light is not emitted on the phase. For this reason, the LED lamp 1 is suitable for the lighting which wants to concentrate light emission in a specific space direction, ie, the road surface, for example, a road lamp, and when used for the lighting, the place where the driver of the car fell. Even if the eye is directed from the direction of the illumination, there is an advantage that the light from the illumination can be prevented from entering the eye.

In the LED lamp 1, the fan 7 is provided on the one side 31 side and the other side 32 side of the substrate 3 near the second side edge 34 of the substrate 3. The back portion of the LED 2 of the heat dissipator 4 carries the gas sent out to the one side 31 side of the substrate 3 by the fan 7 to the back side of the reflector plate 24 of the reflector 22. It is provided with the gas guide surface 24b which guides toward.

After this is sucked by the fan 7, it is guided by the gas guide surface 24b on the back side of the reflecting plate 24, and the adjacent fins 42 and the heat sink body of the heat sink 4 are adjacent. Air K2 which has advanced to the gap surrounded by the portion 41 passes through the radiator body portion 41 and the cover 5 while shaking up and down. For this reason, not only are each fin 42 cooled by the said air K2, but the uniformity of the temperature distribution between the heat sink body part 41 side and the cover 5 side of each fin 42 is accelerated | stimulated. . Thereby, the cooling efficiency by each pin 42 improves, and with this, the cooling of LED2 is also promoted further, and the temperature rise of LED2 can be suppressed. In particular, since the fins 42 are disposed perpendicular to the substrate 3 and arranged in parallel with each other, cooling can be efficiently performed without disturbing the above-described shaking of the air K2.

In the side view, 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 extend across the front and back of the substrate 3, Through the notch part 47, all are guided to the pin 42 on the back side of the substrate 3. As a result, while the size and shape are limited, the outside air can be put in to the maximum and fed to the pins 42, and the cooling can be performed efficiently.

In the LED lamp 1, the radiator 4 faces the fins 42 as a plurality of plate-shaped portions that are long in the direction of the clasp 6 from the fan 7 and are substantially perpendicular to the substrate 3. And arranged in parallel.

The heat dissipation member 4 having the above-described configuration has a large surface area in contact with the air K1 and K2 conveyed by the fan 7, and also allows the air K1 and K2 to flow smoothly, so that the cooling efficiency is good. . Since the LED lamp 1 is equipped with such a heat sink 4 with such a 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 also as a lamp for hermetic lighting fixtures used at gas stations etc., for example.

    << Example 2 >>

FIG. 10 (A) is a front view of the LED lamp 101 of the second embodiment lying on its side, FIG. 10 (B) is a bottom view of the LED lamp 101 of the second embodiment lying on its side, and FIG. It is a top view of the LED lamp 101 of Example 2 lying down, and FIG. 12 is a perspective view which cuts and shows the right side of the LED lamp 101 of Example 2 which laid down sideways.

Hereinafter, about the LED lamp 101 of Example 2, the difference with the LED lamp 1 of Example 1 is demonstrated, and the description about the point similar to the LED lamp 1 of Example 1 is abbreviate | omitted.

As described above, the LED lamp 1 of the first embodiment, as shown in Figs. 5 and 6, the heat dissipating body 4 which is integrally provided with the heat dissipating body part 41 and the plurality of fins 42. ), The base reflector 21 and the top reflector 22 are formed of separate members, respectively. The base reflector 21 and the top reflector 22 are fixed to the heat sink body portion 41 of the heat sink 4 by screwing, respectively.

On the other hand, the LED lamp 101 of Example 2 is equipped with the heat sink 4 (FIG. 5, reference), the base reflector 21 (FIG. 5, reference), and the tower in the LED lamp 1 of Example 1. It differs from the LED lamp 1 of Example 1 in that the reflector 22 (refer FIG. 5, reference) is provided with the body 104 integrally formed. That is, the body 104 includes the body main body 141 (see FIG. 10) and the base reflector 21 (see FIG. 5) corresponding to the radiator main body 41 (FIG. 5, reference). Corresponding base reflector portion 121 (FIG. 10, reference), Top reflector portion 122 (FIG. 10, reference) corresponding to top reflector 22 (FIG. 5, reference), and plurality of pins 142 (FIG. 10, reference) is provided integrally. In addition, the method of integral molding may be performed by die-cutting or shaping | molding.

The body 104 includes a substantially curved plate 141a in which the body main body 141, the base reflector 121, and the top reflector 122 are curved by forming a substantially elliptical plate-like body to form part of a virtual concrete surface. ) Is formed. The part without fin 142 on the back surface side of this substantially curved plate 141a functions as a gas guide surface 124b for guiding gas.

The body main body 141 is formed in a flat circular area formed in the center portion of the curved plate 141a. As for the body main-body part 141, the board | substrate 103 with which the LED 102 was surface-mounted is fixed to the center part of the concave surface 141c of the curved board 141a by screwing.

The base reflector part 121 and the top reflector part 122 are formed in the both side parts of the longitudinal direction of the curved board 141a adjacent to the body main body part 141, respectively.

In addition, the body 104 is provided with a plurality of pins 142 substantially standing on the curved plate 141a on the convex surface side 141b of the curved plate 141a.

Each pin 142 is a plate-like object, substantially extends along the longitudinal direction of the curved plate 141a, and is arranged substantially equally with respect to the body main body 141 at substantially equal intervals in parallel with each other.

The body 104 is inserted into the cylindrical cover 105, and is disposed so that the direction in which each pin 142 extends is parallel to the centerline direction of the cover 105. Therefore, each pin 142 is set such that the length in the extending direction is substantially the same as the length of the cover 105. Moreover, the body main body 141 is arrange | positioned in the vicinity of the centerline of the cover 105, and the upper and lower short sides of each pin 142 abut the inner peripheral surface 151 of the cover 105 in the said arrangement state. It is approaching so as not to touch or touch. For this reason, the upper and lower widths of the pins 142 are individually adjusted for each place along the extending direction.

By the above structure and operation | movement, the body main body part 141, the base reflector part 121, and the top reflector part 122 are formed in the substantially curved board 141a of the integral body which does not have a discontinuous bending part. For this reason, the air sucked in by the fan 107 has a convex shape of the curved plate 141a between the plurality of pins 142 which are provided on the surface side 141b of the convex shape of the curved plate 141a. It can pass smoothly with little stagnation along the surface side 141b, and can be cooled efficiently.

The base reflector 121 and the top reflector 122 are integrated with the body main body 141. Therefore, the base reflector 121 and the top reflector 122 can exert a function as a heat sink similarly to the body main body 141, and the cooling efficiency is improved.

In addition, in the correspondence of the present invention and the embodiment, the rotating means corresponds to the rotating mechanism 8, and similarly to the first reflecting member, the first reflecting member corresponds to the base reflector 21 and the base reflector portion 121, The second reflecting member corresponds to the top reflector 22 and the top reflector portion 122, and the plate-shaped portion corresponds to the pins 42 and 142, but the present invention is not limited to the present embodiment and various other embodiments. Can be in the form

    Industrial availability

This invention can be used for the lighting industry using LED.

One… LED lamp 2... LED
3... Substrate 4... Radiator
5... Cover 6.. Clasp
7... Fan 8... Rotary mechanism
21... Base reflector
22... Top reflector
24b, 124b... Gas guide
41... . Heat sink body portion 42... Fin
121... Base reflector 122... Top Reflector

Claims (5)

LED emitting light,
A substrate provided with one side of the LED,
A heat sink provided on the other side of the substrate,
A transparent cover covering at least one side of the substrate and the LED;
A clasp provided near the first side of the substrate,
An LED lamp provided with the fan provided in the vicinity of the 2nd side of the said board | substrate which becomes a facing surface with the said 1st side. The method of claim 1,
And a rotation means for rotating at least the substrate with respect to the clasp, with an axis parallel to the insertion direction of the clasp as the rotation axis. The method according to claim 1 or 2,
A first reflecting member which reflects light from the LED toward the first side of the substrate, and directs the light toward a space on one side of the substrate;
And a second reflecting member that reflects light from the LED toward the second side of the substrate and is directed toward a space on one side of the substrate. The method of claim 3,
The fan is provided over one side and the other side of the substrate near the second side edge,
The back side of the said 2nd reflecting member is equipped with the gas induction surface which guides the gas sent to the said one surface side by the said fan toward the back part of the said LED of the said heat sink. The method according to any one of claims 1 to 4,
The said heat radiator is a LED lamp of the structure which was arrange | positioned in parallel in the direction of the said clasp from the said fan, and the several plate-shaped part which is substantially perpendicular to the said board | substrate mutually mutually.

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