JP2018190618A - Lamp unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the efficiency of radiating heat of an LED light source by a heat sink.SOLUTION: A headlamp unit 20 includes a heat sink 40 which radiates heat of an LED light source 32. The heat sink 40 includes: a shelf-like part 41 on which the LED light source 32 is placed; and a cylindrical part T which guides air below the shelf-like part 41 upward. The air below the shelf-like part 41 is suctioned into the cylindrical part T and guided upward through chimney effect of the cylindrical part T to improve heat radiation efficiency of the LED light source 32.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a lamp unit including a heat sink that dissipates heat from an LED light source.

  A lamp unit related to this is described in Patent Document 1. As shown in FIG. 7, the lamp unit 100 of Patent Document 1 includes LED light sources 101 provided at an upper portion, a central portion, and a lower portion. The LED light source 101 generally converts 20 to 30 percent of power consumption into visible light, and the rest is converted into heat. For this reason, the lamp unit 100 includes a heat sink 120 that dissipates heat from the LED light source 101. The heat sink 120 includes a square base plate 121 installed in a rearward tilted state, and upper, central, and lower shelf-like portions 123, 124, and 125 are provided on the front surface (front surface) side of the base plate 121. It has been. The LED light sources 101 are installed on the upper, central, and lower shelf parts 123, 124, and 125, respectively.

  Moreover, on each shelf-like part 123, 124, 125 of the heat sink 120, a semi-dome-shaped reflector 103 and a lens 105 for irradiating light generated by the LED light source 101 forward are provided. Further, a plurality of flat plate fins 126 are provided on the back surface (rear surface) side of the base plate 121 of the heat sink 120. The heat generated by the LED light source 101 is transmitted from the shelf portions 123, 124, and 125 of the heat sink 120 to the base plate 121, and is radiated by the flat fins 126 on the back surface of the base plate 121.

JP 2009-266435 A

  In the heat sink 120 of the lamp unit 100 described above, as shown in FIG. 7, upper, central, and lower shelf-like parts 123, 124, and 125 are provided on the front side of the base plate 121, and the lower end of the base plate 121. The portion projects downward with respect to the lower shelf-like portion 125. For this reason, the air below the shelf-like parts 123, 124, 125 is blocked by the front surface of the base plate 121. Therefore, the air that is warmed under the shelf-like parts 123, 124, and 125 and tends to stay is likely to stay at this position. For this reason, the heat dissipation efficiency of the shelf-like portions 123, 124, 125 of the heat sink 120 that receives the heat of the LED light source 101 most and the vicinity thereof are lowered.

  The present invention has been made to solve the above-described problems, and the problem to be solved by the present invention is to improve the heat radiation efficiency of the LED light source by the heat sink.

  The above-described problems are solved by the inventions of the claims. The invention of claim 1 is a lamp unit including a heat sink that dissipates the heat of the LED light source, and the heat sink guides upward a shelf-like portion on which the LED light source is placed and air below the shelf-like portion. And a cylindrical portion.

  According to the present invention, since the LED light source is mounted on the shelf portion of the heat sink, the shelf portion receives the heat of the LED light source most. The heat sink is provided with a cylindrical portion that guides air below the shelf-like portion upward. That is, due to the chimney effect of the cylindrical part, the air below the shelf part of the heat sink is sucked into the cylindrical part and guided upward. For this reason, the air which is warmed under the shelf-like portion of the heat sink and is going to rise does not stay at this position, and the heat dissipation efficiency of the LED light source by the heat sink is improved.

  According to invention of Claim 2, the cylindrical part of a heat sink is provided with the vertical wall part which stands up at the edge position of a shelf-like part, and the thickness of the vertical wall part of the said cylindrical part, and the said shelf-like part The dimension is set larger than the thickness of the other part of the heat sink. For this reason, it becomes easy to transmit the heat | fever of an LED light source from a shelf-shaped part to the vertical wall part of a cylindrical part. Thereby, the temperature of a cylindrical part becomes high and it becomes easy to raise | generate a convection.

  According to invention of Claim 3, the thickness dimension of the shelf-shaped part of a heat sink is set larger than the thickness dimension of the vertical wall part of the said cylindrical part.

  According to the invention of claim 4, the cylindrical portion of the heat sink has a guide wall portion that guides air flowing from the lower side of the shelf-shaped portion toward the tubular portion to the inlet of the tubular portion, rather than the shelf-shaped portion. It is formed so as to protrude downward. For this reason, the air flowing in the direction of the cylindrical portion from the lower side of the shelf-like portion easily flows into the inlet of the cylindrical portion.

  According to the invention of claim 5, the heat sink is provided with side plate portions that support both sides in the width direction of the shelf-like portion from below and further constitute wall portions on both sides in the width direction of the tubular portion. That is, the strength of the heat sink can be increased by connecting the shelf portion and the cylindrical portion by the side plate portion.

  According to invention of Claim 6, the inner side of a cylindrical part is partitioned off by the partition plate. For this reason, the heat dissipation efficiency of the cylindrical portion is improved by the partition plate.

  According to the invention of claim 7, the side plate portions on both sides in the width direction are partitioned in the width direction by the partition plate from the lower side of the shelf-like portion to the inside of the tubular portion. For this reason, the heat dissipation efficiency of the shelf-like portion and the cylindrical portion is improved by the partition plate.

  According to the invention of claim 8, the plurality of fins for guiding the air rising from the lower side of the shelf-like portion through the outside of the tubular portion is provided on the outside of the tubular portion. For this reason, it becomes easy to guide the air that has not been sucked into the cylindrical portion upward along the cylindrical portion.

  According to the present invention, the heat dissipation efficiency of the LED light source by the heat sink can be improved.

It is a model perspective view of a vehicle provided with the lamp unit which concerns on Embodiment 1 of this invention. It is a model longitudinal cross-sectional view (II-II arrow sectional drawing of FIG. 1) of the said lamp unit. It is a model perspective view of the LED light source and heat sink of the said lamp unit. It is a model perspective view of the state which added the reflecting plate to the LED light source of the said lamp unit, and the heat sink. It is a perspective view of the heat sink part. It is a longitudinal section showing the flow of air around the heat sink. It is a model longitudinal cross-sectional view of the conventional lamp unit.

Embodiment 1
Hereinafter, the lamp unit according to Embodiment 1 of the present invention will be described with reference to FIGS. The lamp unit according to this embodiment is a headlamp unit 20 of a vehicle 10 as shown in FIG. Here, front and rear, right and left, and upper and lower shown in the figure correspond to front and rear, right and left, and top and bottom of the vehicle 10 including the headlamp unit 20 according to this embodiment.

<About the configuration outline of the headlamp unit 20>
The headlamp unit 20 is a lamp of the same specification used in a pair of left and right, and is formed symmetrically. As shown in FIG. 2, the headlamp unit 20 includes a housing 21 having an opening 21 h formed on the front side, a lid-like outer lens 23 that closes the opening 21 h of the housing 21, and a light source housed in the housing 21. Device 30.

  Then, the lens edge portion 23f of the outer lens 23 is fitted to the opening edge portion 21e of the housing 21, whereby the housing 21 and the outer lens 23 are configured in a sealed container shape. Breathing holes 21z are provided in the upper and lower portions of the rear wall portion 21b (bottom wall portion) of the housing 21. Further, as shown in FIG. 2, a decorative reflector 25 is provided on the inner side of the outer lens 23 to conceal other than the irradiation lens 35 of the light source device 30 housed in the housing 21 from the outside.

<About the light source device 30>
The light source device 30 is a device that irradiates the light generated by the LED light source 32 forward. As shown in FIG. 2, the light source device 30 includes the LED light source 32, a heat sink 40, a reflection plate 34 for light irradiation, and the irradiation lens 35. ing. The irradiation lens 35 of the light source device 30 is fitted in the circular opening 25 h of the decorative reflector 25. The LED light source 32 is attached to the upper surface 41u of the shelf-like portion 41 of the heat sink 40 as shown in FIGS. On the shelf 41 of the heat sink 40, a light irradiating reflector 34 that reflects the light of the LED light source 32 forward is provided so as to cover the LED light source 32 in a semi-dome shape later. Further, an annular lens support frame 41 e to which the irradiation lens 35 is attached is provided at the tip of the shelf-like portion 41 of the heat sink 40.

<About heat sink 40>
In the LED light source 32, 20 to 30 percent of the power consumption is converted into visible light, and the rest is converted into heat. The heat sink 40 radiates heat generated by the LED light source 32 and is a member used as a support frame for the LED light source 32, the light irradiating reflector 34, and the irradiation lens 35. As shown in FIGS. 3 to 6, the heat sink 40 includes the above-described shelf-like portion 41, the vertical wall portion 43 standing upright on the rear side of the shelf-like portion 41, the shelf-like portion 41, and the vertical wall portion 43. And a substantially L-shaped side plate portion 44 that supports the left and right sides.

  As shown in FIG. 5 and the like, the left and right side plate portions 44 are provided with a front plate portion 44f having a small height dimension and a rear plate portion 44b having a large height dimension. A step 44d is formed between the portions 44b. The shelf-like portion 41 is supported at the upper end position of the front plate portion 44f of the side plate portion 44, and the vertical wall portion 43 is supported at the position of the step 44d. Further, between the rear plate portions 44b of the left and right side plate portions 44, as shown in FIGS. 5 and 6, a horizontal wall portion 45 extending in the left-right direction in a state parallel to the vertical wall portion 43 is provided. Thereby, on the rear side of the shelf-like portion 41, a cylindrical portion T having a square cross section is formed in a chimney shape by the left and right side plate portions 44, the vertical wall portion 43, and the horizontal wall portion 45. Further, a groove portion M extending in the vertical direction is formed on the rear side of the tubular portion T by the rear plate portions 44 b of the left and right side plate portions 44.

  Here, the lower part 45g of the horizontal wall part 45 which comprises the said cylindrical part T has projected below the dimension H rather than the lower surface of the shelf-shaped part 41, as shown in FIG. Thereby, the air located under the shelf-like portion 41 of the heat sink 40 is easily guided to the inlet Te of the tubular portion T. That is, the lower part 45g of the horizontal wall part 45 which comprises the said cylindrical part T is equivalent to the guide wall part of this invention. The left and right side plate portions 44 are partitioned at equal intervals in the left-right direction by a plurality of partition plates 47 parallel to the side plate portions 44. That is, the cylindrical portion T and the groove portion M of the shelf-like portion 41 of the heat sink 40 are partitioned at equal intervals in the left-right direction by the plurality of partition plates 47.

  The thickness dimension of the shelf-like portion 41 of the heat sink 40 that receives the heat of the LED light source 32 most is set to the largest value in the heat sink 40. For example, the thickness dimension of the shelf-like portion 41 is set between about 4 mm and 6 mm. Further, the thickness dimension of the vertical wall portion 43 is set to the thickness dimension next to the shelf-shaped portion 41. Thereby, the heat transmitted from the LED light source 32 to the shelf-like portion 41 of the heat sink 40 is quickly transferred to the vertical wall portion 43. Further, the left and right side plate portions 44, the horizontal wall portion 45, and the partition plate 47 are formed thin with respect to the vertical wall portion 43 and the like and serve as fins. As a material of the heat sink 40, an aluminum alloy, a magnesium alloy, or the like is preferably used.

<About the function of the heat sink 40>
Heat generated when the LED light source 32 is turned on is transferred from the shelf-like portion 41 of the heat sink 40 to the vertical wall portion 43 and the fins such as the left and right side plate portions 44 and the partition plate 47 to be dissipated. On the upper side of the shelf-like portion 41 of the heat sink 40 that becomes the highest temperature by the heat of the LED light source 32, the air heated by the heat radiation of the shelf-like portion 41 rises as shown by the white arrows in FIGS. It is guided from the front side of the light-irradiating reflector 34 to the upper part of the headlamp unit 20.

  Further, in the cylindrical portion T of the heat sink 40, the air heated by the heat radiation of the vertical wall portion 43, the left and right side plate portions 44, and the horizontal wall portion 45 flows upward in the cylindrical portion T at a high flow rate. As a result, the inlet Te of the cylindrical portion T of the heat sink 40 becomes negative pressure (chimney effect). For this reason, below the shelf-like portion 41 of the heat sink 40, the air heated by the heat radiation of the shelf-like portion 41 is sucked into the inlet Te side of the tubular portion T of the heat sink 40 and guided into the tubular portion T. It is burned. Thereby, the air below the shelf-like portion 41 is guided to the upper portion of the headlamp unit 20 through the tubular portion T.

  Here, as described above, the lower portion 45g of the horizontal wall portion 45 constituting the cylindrical portion T of the heat sink 40 protrudes downward from the lower surface of the shelf-like portion 41 by a dimension H as shown in FIG. Therefore, the air below the shelf-like portion 41 is easily sucked into the inlet Te of the tubular portion T. Further, the air that has not been sucked into the inlet Te of the cylindrical portion T of the heat sink 40 is guided upward along the groove M formed on the rear side of the cylindrical portion T. And the air guide | induced to the upper part of the headlamp unit 20 is discharged | emitted outside from the upper breathing hole 21z, as shown in FIG.

<Advantages of the headlamp unit 20 according to this embodiment>
According to the headlamp unit 20 according to the present embodiment, the heat sink 40 is provided with a cylindrical portion T that guides air below the shelf-like portion 41 upward. That is, due to the chimney effect of the tubular portion T, the air below the shelf-like portion 41 of the heat sink 40 is sucked into the tubular portion T and guided upward. For this reason, the air which is warmed under the shelf-like portion 41 of the heat sink 40 and is going to rise does not stay at this position, and the heat dissipation efficiency of the LED light source 32 by the heat sink 40 is improved. Moreover, since the thickness dimension of the shelf-shaped part 41 of the heat sink 40 is set larger than the thickness dimension of the cylindrical part T, the heat dissipation capability of the shelf-shaped part 41 is increased.

  Moreover, since the lower part 45g (guide wall part) is formed in the cylindrical part T (lateral wall part 45) of the heat sink 40 so as to protrude below the shelf part 41, the bottom part 41 It becomes easy to guide the air flowing from the side toward the cylindrical portion T to the inlet Te of the cylindrical portion T. Furthermore, since the inside of the cylindrical portion T is partitioned in the lateral direction by the partition plate 47, the heat dissipation efficiency of the cylindrical portion T is improved by the partition plate 47. A plurality of fins (partition plate 47, left and right side plate portions 44) for guiding the air rising from the lower side of the shelf-like portion 41 through the rear side of the tubular portion T are provided on the rear side of the tubular portion T. Is provided. For this reason, the air that has not been sucked into the tubular portion T can be easily guided upward along the tubular portion T.

<Example of change>
In addition, this invention is not limited to the said embodiment, The change in the range which does not deviate from the summary of this invention is possible. For example, in this embodiment, the example which forms the groove part M in the back side of the cylindrical part T of the heat sink 40 was shown. However, the groove M can be omitted. Further, in the present embodiment, an example is shown in which the left and right side plate portions 44 of the heat sink 40 are partitioned by a plurality of parallel partition plates 47. However, when the distance between the left and right side plate portions 44 is small, the partition plate 47 can be omitted. In the present embodiment, the example in which the present invention is applied to the headlamp unit has been described. However, the present invention can also be applied to other lamp units.

20... Headlamp unit (lamp unit)
32 ... LED light source 40 ... heat sink 41 ... shelf (fin)
43 ··· Vertical wall (cylindrical part)
44... Side plate part (tubular part)
45 .... Horizontal wall (tubular)
45g ... Lower part (guide wall)
47 ... Partition plate (fin)
M: Groove T ... Cylindrical part Te ... Entrance

Claims (8)

A lamp unit including a heat sink that dissipates heat from an LED light source,
The heat sink is a lamp unit including a shelf-like portion on which the LED light source is placed and a cylindrical portion that guides air below the shelf-like portion upward. The lamp unit according to claim 1,
The cylindrical portion of the heat sink includes a vertical wall portion standing at an edge position of the shelf-like portion, and a thickness dimension between the vertical wall portion of the cylindrical portion and the shelf-like portion is that of the heat sink. Lamp unit that is set larger than the wall thickness of other parts. The lamp unit according to claim 2,
The lamp unit in which the thickness dimension of the shelf-like portion of the heat sink is set larger than the thickness dimension of the vertical wall portion of the cylindrical portion. The lamp unit according to any one of claims 1 to 3, wherein
In the tubular portion of the heat sink, a guide wall portion that guides air flowing in the direction of the tubular portion from the lower side of the shelf-like portion to the inlet of the tubular portion protrudes below the shelf-like portion. The lamp unit is formed as follows. The lamp unit according to any one of claims 1 to 4,
The heat sink is a lamp unit provided with side plate portions that support both sides of the shelf-like portion in the width direction from below and further constitute wall portions on both sides of the tubular portion in the width direction. The lamp unit according to any one of claims 1 to 5,
A lamp unit in which the inside of the tubular portion is partitioned by a partition plate. The lamp unit according to claim 5,
The lamp unit between the side plate portions on both sides in the width direction is partitioned in the width direction by the partition plate from the lower side of the shelf-like portion to the inside of the tubular portion. The lamp unit according to any one of claims 1 to 7,
A lamp unit provided with a plurality of fins for guiding air rising from the lower side of the shelf-like portion through the outside of the tubular portion on the outside of the tubular portion.

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