JP5359502B2 - Gaze guidance light - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a visual line guide light, capable of preventing deterioration of visibility of light from a light source in snow. <P>SOLUTION: The visual line guide light includes a case 12 provided in a predetermined height position from the ground and containing the light source for visual line guidance, and an upper through-hole 30 with a water-impermeable filter provided on the upper surface of the case 12. The bottom part of the case 12 is partitioned by a lower closing lid 27, the lower closing lid 27 including a lower through-hole 28. The upper through-hole 30 and the lower through-hole 28 include steam-impermeable upper filter 31 and lower filter 29 respectively. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a line-of-sight guide lamp installed in a snowy area.

  2. Description of the Related Art Conventionally, a line-of-sight guide lamp that is provided on the side of a road and clearly indicates the shape of the road by causing a driver of a vehicle traveling on the road to visually recognize light emitted from a light source is known (for example, Patent Document 1). reference). In this type of gaze guidance light, there is a gaze guidance light that is assumed to be installed in a snowy area (see, for example, Patent Document 2).

JP 2003-41533 A

JP 2003-193432 A

However, in the gaze guidance lamp having a structure in which the lower pole and the upper translucent hood (cylindrical case) are connected as in the gaze guidance lamp of Patent Document 2, the light emitting unit is in a snowy situation. When the (light source) emits light, an air passage for the air flowing upward is formed by the heat of the light source, and air containing a large amount of water vapor flows into the cylindrical case through the pole. There is a problem that the inside is condensed and the light visibility of the light source is lowered.
The present invention has been made in view of the above-described circumstances, and an object of the present invention is to provide a line-of-sight guide light that prevents the light visibility of a light source from being deteriorated during snowfall.

To achieve the above object, the present invention is provided et is at a predetermined height position from the ground, has a cylindrical casing that contains the light source for visual guidance, the upper surface of the cylindrical case, penetrations In a line-of-sight guide lamp having a hole, the bottom of the cylindrical case is partitioned by a partition plate, a lower through hole is provided in the partition plate, and a water vapor impermeable filter is provided in each of the through hole and the lower through hole. It is characterized by that.
According to this configuration, the air is heated by the heat radiation of the light source in the case, and the air flows into the case through the lower through hole provided in the partition plate. It flows out of the case through a through hole provided in the upper surface. Here, since the water vapor non-permeable filter is provided in the through hole and the lower through light, the air flowing into the case is the air from which the water vapor has been removed. For this reason, even when the outside air contains a large amount of water vapor during snowfall, the water vapor is prevented from flowing into the case, and condensation is prevented from occurring in the case. It is prevented that the visibility of is reduced.
Further, according to this configuration, after the light source is cooled by the air flowing into the case, it is possible to prevent the light visibility of the light source from being lowered as described above, and to extend the life of the light source. it can.
Further, according to this configuration, since the water vapor is prevented from flowing into the case, it is possible to prevent the light source from being adversely affected by the water vapor.

Here, in the line-of-sight guide lamp of the above invention, the lower through hole may be provided at a position shifted from below the through hole.
According to this configuration, in the case, not the air path that flows linearly upward in the case, but the air path that flows while twisting upward in the case from the lower through hole toward the through hole is formed. The For this reason, the amount of air in contact with the light source can be increased as compared with the case of the air path that flows linearly upward in the case, thereby further improving the cooling efficiency of the light source. it can.

In the line-of-sight guide lamp of the above invention, the cylindrical case may have an inverted conical shape.
According to this configuration, the wind speed of the air flowing in the lower part of the case is faster than the wind speed of the air flowing in the upper part of the case, and is guided by the inclination of the case and is tilted downward on the case surface. Air flows. And the snow which adheres to the case is scraped away by the air flowing while tilting downward on the surface of the case. Thereby, the adhesion of snow to the case is reduced, and the light visibility of the light source can be prevented from being lowered.

In the line-of-sight guide lamp according to the invention, the cylindrical case has translucency at a position corresponding to the light transmission position of the light source, and has a pointed portion sharpened toward the outside of the cylindrical case. And you may make it provide the snow split part extended in an up-down direction.
According to this configuration, when snow is falling laterally toward the position corresponding to the light transmission position of the light source in the case, the snow is crushed by the snow split part, and it is difficult for the snow to adhere to the surface of the case. Furthermore, air flows along the outer periphery by the snow split portion, and the snow that adheres to the surface of the case is scraped off by the air flowing along the surface of the case. Accordingly, it is possible to reduce the adhesion of snow to the surface of the case and to prevent the light visibility of the light source unit from being lowered.

Further, in the line-of-sight guide lamp according to the invention, an umbrella portion that covers at least the cylindrical case in a top view is provided above the cylindrical case, and the air discharged from the through hole is brought into contact with the lower surface of the umbrella portion. You may do it.
According to this configuration, during snowfall, snow accumulates on the umbrella part, and the umbrella part is warmed by warm air heated by the light source discharged from the through hole, and the snow deposited on the umbrella part melts. Here, since the water generated by melting the snow falls without contacting the case, the visibility of the light of the light source is reduced due to the water generated by melting the snow contacting the case. Can be prevented.

In the line-of-sight guide lamp of the above invention, the umbrella portion may have a conical shape.
According to this configuration, it is possible to prevent the visibility from being lowered while preventing the snow from accumulating on the umbrella portion.

Moreover, in the line-of-sight guide lamp of the above invention, the cylindrical case may be subjected to ultraviolet ray cut processing.
According to this configuration, the case can prevent the light source unit housed in the case from being directly irradiated with external light including ultraviolet rays, and therefore, the light source unit can be prevented from being adversely affected by the ultraviolet rays.

  ADVANTAGE OF THE INVENTION According to this invention, it can prevent that the visibility of the light of a light source falls at the time of snow accumulation.

It is a front view of the line-of-sight guide lamp concerning a 1st embodiment. It is a left view of a line-of-sight guide light. It is a figure which shows a case, an upper obstruction | occlusion lid, and a lower obstruction | occlusion lid typically. It is a figure which shows typically the gaze guidance lamp which concerns on 2nd Embodiment. It is a figure which shows typically the gaze guidance lamp which concerns on 3rd Embodiment. It is a figure which shows typically the gaze guidance lamp which concerns on 4th Embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
<First Embodiment>
FIG. 1 is a front view of a line-of-sight guide lamp 1A according to the present embodiment, and FIG. 2 is a left side view of the line-of-sight guide lamp 1A. 1 and 2 are partially sectional views.
A plurality of line-of-sight guide lights 1A are provided, for example, at intervals along the road, and the shape of the road is clearly shown by allowing a driver of a vehicle traveling on the road to visually recognize light from the light source unit 10 described later. Is. In particular, the line-of-sight guide lamp 1A according to the present embodiment is assumed to be provided in a snowy area, and the light visibility of the light source unit 10 is reduced due to snowfall under a snowy condition. Prevents the decline.

As shown in FIGS. 1 and 2, the line-of-sight guide lamp 1A includes a base portion 11 (not shown in FIG. 2), a case 12 (cylindrical case) connected above the base portion 11, and this case. 12 and a light source unit 10 for guiding the line of sight housed in the line 12.
The base portion 11 is a member that is fitted into and fixed to a pole 15 that is erected on the ground such as a roadside, and is a base member 16 that is formed by bending it into a square shape when viewed from the front (not shown in FIG. 2). It has. An electronic device 18 including a drive circuit for an LED 17 (described later) is attached to a side surface of the base member 16, and a power supply cable 19 extending upward inside the pole 15 is connected to the electronic device 18. Is done.
A constricted portion 20 that is constricted inward is formed slightly upward in the middle of the base member 16 in the vertical direction, and a cylindrical connecting portion 21 is screwed to the base member 16 above the constricted portion 20. It is fixed.

The connecting portion 21 is a member for connecting the case 12 and the pole 15 by connecting the base member 16 and the case 12, and is fixed when the connecting portion 21 is inserted into the case 12. The base member 16 and the case 12 are connected. Specifically, the case 12 has a cylindrical shape extending in the vertical direction, and the inner peripheral shape thereof is formed substantially the same as the outer peripheral shape of the connecting portion 21. The connecting portion 21 is inserted into the case 12 in a state where the outer periphery of the connecting portion 21 is in contact with the inner periphery of the case 12, and thereby the case 12 is fixed to the connecting portion 21. Two grooves 22 and 22 formed along the outer periphery are provided on the outer periphery of the connecting portion 21 with an interval in the vertical direction. The grooves 22 and 22 include an elastic O-ring 23, 23 is fitted, and these O-rings 23 and 23 ensure airtightness at the contact portion between the inner periphery of the case 12 and the outer periphery of the connecting portion 21. More specifically, the connecting portion 21 is inserted into the case 12 with the O-rings 23, 23 being pressed and elastically deformed by the inner periphery of the case 12, and the O-rings 23, 23 are connected to the inner periphery of the case 12. A gap between the outer periphery of the connecting portion 21 is closed, and airtightness at the contact portion between the inner periphery of the case 12 and the outer periphery of the connecting portion 21 is ensured.
A ring member 24 is provided at the upper end of the pole 15, and the case 12 is inserted into the connecting portion 21 so that the lower end of the case 12 contacts the ring member 24.

  The case 12 is a cylindrical member having translucency and extending in the vertical direction. The surface of the case 12 is subjected to ultraviolet ray cut processing. For example, a coating liquid having an ultraviolet absorption function is applied to the surface of the case 12, and a filter having an ultraviolet reflection function is attached to the surface of the case 12, for example. It is prevented that the ultraviolet light contained in sunlight is directly irradiated to the light source unit 10 accommodated in the case 12. This prevents the LED 17 included in the light source unit 10 and the case 12 itself from being adversely affected by ultraviolet rays. In particular, the ultraviolet rays irradiated to the LED 17 are cut to reduce the aging deterioration of the LED 17 and to extend the life of the line-of-sight guide lamp 1A.

FIG. 3 is a diagram schematically showing the case 12, the upper closing lid 26 that closes the upper end opening of the case 12, and the lower closing lid 27 (partition plate) that closes the lower end opening of the case 12.
Inside the case 12, a lower closing lid 27 is provided at the upper end of the connecting portion 21 to hermetically divide the upper end opening of the connecting portion 21. The lower closing lid 27 is arranged in the vertical direction on the lower closing lid 27. Two lower through holes 28 (see also FIG. 3) are formed, and a lower filter 29 (see also FIG. 3) is provided in each of the lower through holes 28. The lower closing lid 27 partitions the connecting portion between the case 12 and the pole 15 by partitioning the upper end opening of the connecting portion 21 located at the bottom of the case 12. In addition to dust, the lower filter 29 includes a water vapor impermeable filter that does not transmit water and water vapor. The lower filter 29 removes dust and water vapor from the air passing through the lower through hole 28. . For example, the lower filter 29 may be configured by combining a filter capable of removing dust and water and a desiccant such as silica gel. The lower filter 29 is provided in a state in which the entire area of the lower through hole 28 is covered so that air passing through the lower through hole 28 passes through the lower filter 29 without leakage.
In the present embodiment, as described above, the O-rings 23 and 23 ensure airtightness at the contact portion between the inner periphery of the case 12 and the outer periphery of the connecting portion 21, so It flows into the case 12 only through 28.

  Further, the upper end of the case 12 is provided with an upper closing lid 26 that hermetically closes the upper end opening of the case 12. The upper closing lid 26 has two upper penetrating holes that penetrate the upper closing lid 26 in the vertical direction. A hole 30 (through hole) (see also FIG. 3) is formed, and an upper filter 31 (FIG. 3) is provided in each of the upper through holes 30. The upper closing lid 26 constitutes the upper surface of the case 12. Similar to the lower filter 29, the upper filter 31 is a filter that is impermeable to water and water vapor in addition to dust, and the upper through hole 30 so that air that passes through the upper through hole 30 passes through the upper filter 31 without leakage. It is provided in a state of covering the entire area. The air in the case 12 is exhausted to the outside through the upper through hole 30.

  As shown in FIG. 3, each of the lower through holes 28 is formed at a position shifted from a position corresponding to the lower part of the upper through hole 30 in the lower closing lid 27. For this reason, although details will be described later, the air that has flowed into the case 12 through the lower closing lid 27 is not an air path that flows linearly upward in the case 12 in the case 12, but in FIG. As shown by the arrow Y1, an air passage that flows while twisting upward in the case 12 is formed.

  Inside the case 12, the light source mounting portion 35 is fixed to the lower closing lid 27 with screws. The light source attachment portion 35 is a member for fixing and positioning the light source portion 10 inside the case 12, and extends in the vertical direction with the left attachment portion 36 and the right attachment portion 37, which are flat members, facing each other. Exist. Between the left mounting portion 36 and the right mounting portion 37, a light source mounting portion 35 includes a substrate 38 provided in the light source unit 10 and a back plate 39 provided on the back side of the substrate 38 so as to face the substrate 38. An upper screw receiving portion 40 (FIG. 2) and a lower screw receiving portion 41 (FIG. 2) are interposed.

The light source part 10 is attached to the light source attachment part 35. The light source unit 10 includes a substrate 38 and the LEDs 17 arranged in a matrix on the substrate 38.
The substrate 38 is formed from a highly thermally conductive material, and the heat generated by the LEDs 17 is efficiently radiated through the substrate 38. The substrate 38 is fixed to the light source mounting portion 35 by being screwed to the upper screw receiving portion 40 and the lower screw receiving portion 41.
The LED 17 includes a light emitting part 42 in which a light emitting diode element is molded in a resin material or the like, and a sealing body formed from an epoxy resin or the like that seals the light emitting part 42. Driving power is supplied to the LED 17 via a power supply line (not shown).
In the present embodiment, the LED 17 can emit light of two colors, green and orange, so that the driver of the vehicle can effectively and surely recognize the light of the LED 17 of the light source unit 10. Furthermore, the maximum luminance of the LED 17 of the light source unit 10 is 25000 cd / m ² or more, and the half-value angle is 15 degrees.
A back plate 39 is provided on the back side of the substrate 38 so as to face the substrate 38 through a gap for releasing heat of the substrate 38. The back plate 39 is fixed to the light source mounting portion 35 by being screwed to the upper screw receiving portion 40 and the lower screw receiving portion 41.

  When the LED 17 emits light, the air inside the case 12 is warmed by heat radiation from the LED 17. Due to this, after passing through the pole 15, the air that flows in from the lower through hole 28 formed in the lower closing lid 27 flows upward in the case 12, and the upper portion formed in the upper closing lid 26. An air flow path for exhausting air from the through hole 30 to the outside is formed. When there is snow, the air passing through the pole 15 is air that contains a large amount of water vapor due to snow.

Here, in the present embodiment, as described above, the O-rings 23 and 23 ensure airtightness at the contact portion between the inner periphery of the case 12 and the outer periphery of the connecting portion 21. Air flows only from the through hole 28. The lower through hole 28 is provided with a water vapor impermeable lower filter 29, and the air flowing into the case 12 through the lower through hole 28 is air from which dust, water and water vapor have been removed by the lower filter 29. It is. Accordingly, it is possible to prevent the inner periphery of the case 12 from being contaminated by the dust of the air flowing into the case 12 and the dew condensation on the inner periphery of the case 12, thereby reducing the light visibility of the light source unit 10. Is prevented.
Further, since dust and water vapor are removed from the air flowing into the case 12 by the lower filter 29, it is prevented that the LED 17 is adversely affected by the dust and water vapor.
Further, when the LED 17 emits light, the LED 17 is cooled by the air flowing into the case 12. Thereby, LED17 is cooled efficiently and lifetime improvement of LED17 is achieved.
In particular, in the present embodiment, an air passage that flows while twisting upward in the case 12 is formed in the case 12 instead of an air passage that flows linearly upward in the case 12. For this reason, compared with the case of the air path which flows linearly upwards in the case 12, the amount of air contacting the LED 17 can be increased, thereby further improving the cooling efficiency of the LED 17. Can do.

A cylindrical umbrella mounting portion 45 extending in the vertical direction is provided at the approximate center of the upper closing lid 26 that closes the upper end opening of the case 12. The umbrella mounting portion 45 includes an umbrella portion 46. It is attached by screwing.
The umbrella portion 46 is a member having a U-shaped cross-section, and covers the upper surface of the case 12 so as to extend in parallel with the upper surface of the case 12 and an outer periphery of the umbrella top surface portion 47. And an umbrella side surface portion 48 extending downward from the top. As shown in FIG. 1, the diameter K1 of the umbrella top surface portion 47 is larger than the diameter K2 of the case 12, and the umbrella portion 46 covers the case 12 in a top view. A space 49 is formed at a location surrounded by the umbrella top surface portion 47, the umbrella side surface portion 48, and the upper closing lid 26, and a gap 50 is formed between the lower end 48a of the umbrella side surface portion 48 and the upper closing lid 26. Is formed.

When the snow falls, the umbrella 46 melts the snow accumulated on the top surface of the line-of-sight guide light 1A and flows on the outer periphery of the case 12, and the water flowing through the outer periphery of the case 12 makes the light of the light source 10 visible in the snow. Is to prevent the decrease.
More specifically, snow falling downward during snowfall accumulates on the upper surface of the umbrella top surface portion 47 as indicated by reference numeral 51 in FIG. Here, air heated by heat radiation of the LED 17 flows into the space 49 from the upper through hole 30 formed in the upper closing lid 26, and the air that has flowed into the space 49 is exhausted to the outside through the gap 50. (See arrow Y2 in FIG. 1). For this reason, the umbrella part 46 is heated by the warm air flowing into the space 49 from the case 12, and the snow accumulated on the upper surface of the umbrella top surface part 47 is melted. The melted snow flows along the umbrella side surface portion 48 of the umbrella portion 46 and falls as water droplets vertically downward from the lower end 48a of the umbrella side surface portion 48, as indicated by reference numeral 52 in FIG. As described above, since the diameter K1 of the umbrella top surface portion 47 is larger than the diameter K2 of the case 12, water drops falling vertically downward from the lower end 48a of the umbrella side surface portion 48 are in contact with the outer periphery of the case 12. Fall without. As described above, the snow accumulated on the top surface of the line-of-sight guide lamp 1A melts and flows around the outer periphery of the case 12, thereby preventing the light visibility of the light source unit 10 from being lowered.
In the present embodiment, a gap 50 is formed between the lower end 48 a of the umbrella side surface portion 48 and the upper closing lid 26, and the air blown upward from the upper through hole 30 stays in the space 49. Without being exhausted through the gap 50. For this reason, the outflow of air from the upper through-hole 30 is inhibited due to the retention of air in the space 49, thereby preventing the air flow in the case 12 from being inhibited.

As described above, the line-of-sight guide lamp 1A according to the present embodiment is configured by connecting the case 12 containing the light source unit 10 for line-of-sight guidance to the upper part of the pole 15 erected on the ground. An upper through hole 30 is formed in the upper closing lid 26 constituting the upper surface of the case 12. The connecting portion between the pole 15 and the case 12 is partitioned by a lower closing lid 27, a lower through hole 28 is provided in the lower closing lid 27, and a water vapor impermeable upper filter is provided in each of the upper through hole 30 and the lower through hole 28. 31 and a lower filter 29 were provided.
According to this, air is heated by heat radiation of the light source unit 10 in the case 12, air flows from the pole 15, which is outside the case 12, through the lower through hole 28, and the air that has flowed into the case 12 It flows out through the upper through hole 30 to the outside, which is outside the case 12. Here, the lower through hole 28 is provided with a water vapor impermeable lower filter 29. For this reason, even when the outside air contains a large amount of water vapor during snow accumulation, the water vapor is prevented from flowing into the case 12, thereby preventing condensation from occurring in the case 12. It is prevented that the visibility of the light of the part 10 falls.
In particular, after the LED 17 of the light source unit 10 is cooled by the air flowing into the case 12, the light visibility of the light source as described above can be prevented from being lowered, and the life of the LED 17 can be increased at the same time. Can do.
Furthermore, since the water vapor is prevented from flowing into the case 12, it is possible to prevent the light source unit 10 from being adversely affected by the water vapor.

In the present embodiment, the case 12 is provided with the lower through hole 28 at a position shifted from the lower side of the upper through hole 30.
According to this, in the case 12, the wind flowing while twisting upward in the case from the lower through hole 28 toward the upper through hole 30 instead of the air path flowing linearly upward in the case 12. A path is formed. For this reason, compared with the case of the air path which flows linearly upwards in the case 12, the amount of air contacting the light source unit 10 can be increased, thereby further improving the cooling efficiency of the light source. Can be planned.

Further, in the present embodiment, an umbrella portion 46 that covers at least the case 12 in a top view is provided above the case 12, and the case 12 is arranged such that air discharged from the upper through hole 30 contacts the lower surface of the umbrella portion 46. An upper through hole 30 is formed in the upper part.
According to this, during the snowfall, snow accumulates on the umbrella part 46, and the umbrella part 46 is warmed by the warm air heated by the light source part 10 discharged from the upper through hole 30, and accumulates on the umbrella part 46. Snow will melt. Here, since the water generated by melting the snow falls without contacting the case 12, the light generated by the melting of the snow contacts the case 12, and thus the light visibility of the light source unit 10 is increased. It can be prevented from decreasing.

Second Embodiment
Next, a second embodiment will be described.
FIG. 4 is a diagram schematically showing a right side view of the line-of-sight guide lamp 1B in order to explain the line-of-sight guide lamp 1B according to the present embodiment. In FIG. 4, the same components as those described in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.
The line-of-sight guide lamp 1B according to the present embodiment is different from the first embodiment described above in that the shape of the umbrella portion 46b is a conical shape.
The umbrella portion 46 b includes a conical cone portion 55 having a cavity formed therein, and a space 56 is formed between the lower surface of the cone portion 55 and the upper closing lid 26. As shown to FIG. 4 (A), the inclination | tilt angle M with respect to the horizontal direction of the cone part 55 is 20-50 degree | times. The diameter K3 of the lower surface of the conical portion 55 is larger than the diameter K2 of the case 12. Further, a gap 57 is formed between the lower end 55 a of the conical portion 55 and the upper closing lid 26. The air blown upward from the upper through hole 30 formed in the upper closing lid 26 flows into the space 56 as shown by the arrow Y3 in FIG. Exhausted.

  Thus, since the umbrella part 46b has a conical shape, the snow that has fallen on the umbrella part 46b during the snowfall corresponds to the inclination of the upper surface of the cone part 55 as shown in FIG. (See arrow Y4 in FIG. 4B). Here, the umbrella part 46b is heated by the air blown out from the upper through-hole 30, as in the first embodiment. For this reason, the snow deposited on the umbrella part 46b melts in the process of sliding on the upper surface of the cone part 55, and falls as a water droplet from the lower end 55a of the cone part 55 as shown in FIG. As described above, since the diameter K3 of the lower surface of the conical portion 55 is larger than the diameter K2 of the case 12, water drops falling vertically downward from the lower end 55a of the conical portion 55 are in contact with the outer periphery of the case 12. Fall without. Thereby, it is prevented that the visibility of the light of the light source part 10 falls by the water produced | generated by melting the snow which fell on the top | upper surface of the line-of-sight guide light 1B flowing on the outer periphery of the case 12.

As described above, the line-of-sight guide lamp 1B according to the present embodiment has the umbrella portion 46b having a conical shape.
According to this, it is possible to prevent the visibility from deteriorating while preventing the snow from accumulating on the umbrella part 46b.

<Third Embodiment>
Next, a third embodiment will be described.
FIG. 5 is a diagram schematically showing a right side view of the line-of-sight guide lamp 1C in order to describe the line-of-sight guide lamp 1C according to the present embodiment. In FIG. 5, the same components as those described in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.
The line-of-sight guide lamp 1C according to the present embodiment differs from the first embodiment described above in that the shape of the case 12b is not a cylindrical shape but an inverted conical shape.
Here, during a stormy snow, as indicated by an arrow Y5 in FIG. 5, the case 12b is directed sideways so as to face the front surface of the case 12b, that is, the light transmission surface (hereinafter referred to as “transmission surface”) of the light source unit 10 in the case 12b. Assume that it is snowing. Under such circumstances, it is conceivable that snow adheres to the transmission surface of the case 12b and the light visibility of the light source unit 10 decreases. Based on this, in the present embodiment, in the situation of stormy snow and snow falling sideways toward the transmission surface of the case 12b, it is possible to reduce the adhesion of snow to the transmission surface of the case 12b. This prevents a decrease in light visibility.

Specifically, as shown in FIG. 5, the case 12b has an inverted conical shape, and the inclination angle α with respect to the vertical direction is in the range of 5 to 20 degrees (15 degrees in the present embodiment). Since the case 12b has an inverted conical shape as described above, the wind speed of the air flowing through the lower part of the case 12b becomes faster than the wind speed of the air flowing through the upper part of the case 12b during the stormy snow as described above. As shown by the arrow Y6 in FIG. 5, air flows on the surface of the case 12b while being inclined downward toward the back side, as indicated by the arrow Y6 in FIG. And the snow which adhered to the case 12b is scraped away by the air which flows while inclining downward on the surface of this case 12b toward the back side. Thereby, the adhesion of snow to the case 12b is reduced, and the light visibility of the light source unit 10 is prevented from being lowered.
Furthermore, since the case 12b has an inverted conical shape, the snow attached to the case 12b is likely to fall by its own weight as compared with the case of a cylindrical shape or a conical shape, and this also causes the snow to adhere to the case 12b. Has been reduced.

As described above, the case 12b of the line-of-sight guide lamp 1C according to the present embodiment has an inverted conical shape.
According to this configuration, the wind speed of the air flowing through the lower part of the case 12b is faster than the wind speed of the air flowing through the upper part of the case 12b, being guided by the inclination of the case 12b and being inclined downward, Air flows over the surface. And the snow which adhered to case 12b is scraped off by the air which flows while inclining below on the surface of this case 12b. Thereby, the adhesion of snow to the case 12b is reduced, and the light visibility of the light source unit 10 can be prevented from being lowered.

<Fourth embodiment>
Next, a fourth embodiment will be described.
FIG. 6 is a diagram schematically showing a plan view and a right side view of the line-of-sight guide lamp 1D for explaining the line-of-sight guide lamp 1D according to the present embodiment. In FIG. 6, the same components as those described in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.
As shown in FIG. 6, in the line-of-sight guide lamp 1D according to the fourth embodiment, a snow split portion 60 is provided outside the transmission surface of the case 12 described above. In the snow split portion 60, a member having a translucent triangular shape in a top view extends in the vertical direction of the case 12 beyond at least the entire vertical direction of the light emitting surface of the light source unit 10. A tip portion 61 is formed at the tip of the snow split portion 60 toward the outside. The angle β of the tip 61 is set to a relatively sharp angle of 10 to 30 degrees.

As in the third embodiment described above, the line-of-sight guide lamp 1D according to this embodiment has snow attached to the transmission surface of the case 12 under the situation where snow is falling laterally toward the transmission surface of the case 12, It prevents that the light visibility of the light source part 10 falls.
Specifically, in the situation as described above, the snow falling toward the transmission surface of the case 12 contacts the pointed portion 61 of the snow split portion 60 and is crushed by the sharply pointed pointed portion 61. This makes it difficult for the snow to adhere to the case 12 as compared with the case where the snow as it is in contact with the case 12. In particular, when a snow lump that is a snow lump has fallen toward the transmission surface of the case 12, the snow lump contacts the pointed end 61 of the snow split 60, and the snow lump is crushed by the pointed end 61, A snow mass is prevented from adhering to the case 12.
Further, as shown by an arrow Y7 in FIG. 6, an air passage for the air flowing along the outer periphery of the case 12 is formed by being guided by the inclination of the snow split portion 60. The air that has already adhered to the case 12 is scraped off by the air flowing along the outer periphery of the case 12, and snow is prevented from adhering to the transmission surface of the case 12.

As described above, in the present embodiment, at the position corresponding to the light transmission position of the light source unit 10 in the case 12 of the line-of-sight guide lamp 1 </ b> D, the tip has a translucency and is pointed toward the outside of the case 12. The snow split part 60 which has the part 61 and extends in the up-down direction is provided.
According to this configuration, when snow is falling laterally toward the position corresponding to the light transmission position of the light source in the case 12, the snow is crushed by the snow split portion 60, and it is difficult for the snow to adhere to the surface of the case 12. . Further, air flows along the outer periphery by the snow split portion 60, and the snow that adheres to the surface of the case 12 is scraped off by the air flowing along the surface of the case 12. Accordingly, it is possible to reduce the adhesion of snow to the surface of the case 12 and to prevent the light visibility of the light source unit 10 from being lowered.

The above-described embodiment is merely an aspect of the present invention, and can be arbitrarily modified and applied within the scope of the present invention.
For example, in each of the above-described embodiments, the cases 12 and 12b are connected to the pole 15. However, the cases 12 and 12b are not limited to those connected to the ball 15, but may be a predetermined part such as a median strip or a guardrail. It may be fitted and connected to the position. That is, the cases 12 and 12b only need to be provided at a predetermined height position from the ground.
In each embodiment described above, the LED 17 is used as the light source. However, the present invention is not limited to this, and a mercury lamp, a high-pressure sodium lamp, or the like may be used as the light source.

1A, 1B, 1C, 1D Line-of-sight guide light 10 Light source (light source)
12, 12b Case (tubular case)
27 Lower closing lid 28 Lower through hole 29 Lower filter (filter)
30 Upper through hole (through light)
31 Upper filter (filter)
46, 46b Umbrella part 60 Snow split part 61 Pointed part

Claims (7)

Provided al is the predetermined height from the ground, has a cylindrical casing that contains the light source for visual guidance, the upper surface of the cylindrical case, the visual guidance lamp having a transmural hole,
Line-of-sight guidance characterized in that the bottom of the cylindrical case is partitioned by a partition plate, a lower through hole is provided in the partition plate, and a water vapor impermeable filter is provided in each of the through hole and the lower through hole. light.   The line-of-sight guide lamp according to claim 1, wherein the lower through hole is provided at a position shifted from below the through hole.   The line-of-sight guide lamp according to claim 1, wherein the cylindrical case has an inverted conical shape.   A snow split which has translucency at a position corresponding to the light transmission position of the light source in the cylindrical case and has a pointed portion sharpened toward the outside of the cylindrical case and which extends in the vertical direction. The line-of-sight guide lamp according to claim 1, further comprising a portion.   The umbrella part which covers at least the said cylindrical case in the top view is provided above the said cylindrical case, and the air discharged | emitted from the said through-hole is made to contact the lower surface of this umbrella part. The line-of-sight guide light according to any one of the above.   The line-of-sight guide lamp according to claim 5, wherein the umbrella portion has a conical shape.   The line-of-sight guide lamp according to any one of claims 1 to 6, wherein the cylindrical case is subjected to an ultraviolet ray cut process.

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