JP2012227007A - Embedded type illuminating lamp - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an embedded type illuminating lamp, in which a lighting body is prevented from being damaged due to water which has intruded in a base and is frozen.SOLUTION: The embedded type illuminating lamp 1 comprises: a lighting body 2 having a light source 18 and an outgoing port 15 through which emission light of the light source 18 is emitted, on an upper surface 9a side; a base 6 formed in a bottomed box shape having an opening 39, and embedded in the ground 3, to attach the lighting body 2 to the opening 39; and an anti-freezer 5 disposed in the base 6 so as to dissolve into water having intruded in the base 6.

Description

  Embodiments described herein relate generally to an embedded illumination lamp that is embedded in a ground.

  As this type of embedded illumination light, for example, an embedded air traffic light that is installed on a runway or taxiway of an airport and guides an aircraft is known. This embedded aerial sign lamp is provided with a lamp, and is embedded in the road surface with the upper part of the lamp projecting slightly from the road surface, and is provided on the upper side of the lamp toward the side. Light is emitted from the window via the exit groove so that it can be seen by the aircraft operator.

  The lamp body is embedded in a base embedded in the road surface via a spacer and an adjustment ring. The base is connected to a hand hole provided with a rubber transformer by piping, and a power line is drawn into the base through the piping from the hand hole. This power supply line is connected to the lamp body via a receptacle or the like (see, for example, Patent Document 1). In addition, the lamp body is liquid-tightly attached to the base side through a waterproof packing, so that moisture such as rainwater does not enter the base.

  However, water enters the base from the handhole side through the pipe. This is because a supplier who installs an embedded aerial beacon wire the power line without interposing waterproof packing or the like in the pipe. In the base, the infiltrated water may accumulate accordingly and may remain until it reaches the lamp.

JP 2008-223253 A (7th page, FIG. 2)

  In recent years, a light-emitting diode that generates a relatively small amount of heat is used as a light source disposed in a lamp. And in airports in cold regions, the ground may freeze.

  If the ground freezes while the lamp body is immersed in water, the temperature drop of the water cannot be prevented due to the heat generated by the light emitting diode, and the water solidifies and the volume expands. And the pressure accompanying expansion | swelling was added to the lamp body from the ice formed by this solidification, and the lamp body might be destroyed.

  An object of an embodiment of the present invention is to provide an embedded illumination lamp in which water that has entered a base is solidified and the lamp body is prevented from being destroyed.

  The embedded illumination lamp of the embodiment includes a lamp body, a base, and an antifreezing agent.

  The lamp body has a light source and an exit through which light emitted from the light source is emitted on the upper surface side.

  The base is formed in a bottomed box shape having an opening. Then, the lamp is embedded in the ground and attached to the opening.

  The antifreezing agent is disposed in the base so as to dissolve in the water that has entered the base.

  According to the embodiment of the present invention, the antifreezing agent dissolves in the water that has entered the base, so that the freezing point of water is lowered. Therefore, even if the temperature of the ground in which the base is embedded is lowered, the base This makes it difficult for the water inside to solidify, thereby preventing the lamp from being destroyed by pressure applied from ice formed by the solidification of the water that has entered the base.

It is a schematic top view of the embedded illumination lamp which shows embodiment of this invention. Similarly, it is a schematic longitudinal cross-sectional view of an embedded illumination lamp. Similarly, it is a block diagram which shows the wiring to an embedded illumination lamp.

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

  The embedded illumination lamp according to the present embodiment is an embedded aerial beacon lamp 1 that is embedded in a ground (road surface) such as an airport runway or taxiway, and is configured as shown in FIGS. The

  In FIG. 3, an embedded aerial beacon lamp 1 includes a lamp body 2, an installation body 4 attached to the ground body (road surface) 3 with the lamp body 2 attached thereto, and an installation body 4 attached to the lamp body 2. An antifreezing agent 5 disposed inside is provided. The installation body 4 includes a bottomed and substantially cylindrical base 6, a substantially cylindrical spacer 7 for adjusting the embedding depth attached on the base 6, and a horizontal attached on the spacer 7. An annular adjustment ring 8 for adjusting the shaft is provided. The installation body 4 is embedded and installed so that the periphery of the upper surface 8 a of the adjustment ring 8 is substantially the same height as the ground 3.

  In FIG. 2, the lamp body 2 is formed in a split structure with a substantially disc-shaped upper lamp body 9 and a substantially dish-shaped lower lamp body 10. The upper lamp body 9 and the lower lamp body 10 are covered with each other via an O-ring 11 and fixed with screws 12. Thereby, the internal space 13 is formed liquid-tight. The upper lamp body 9 is formed by casting a high-strength metal such as aluminum (Al), and the lower lamp body 10 is formed by, for example, aluminum die casting.

  The upper surface 9a of the upper lamp body 9 is bulged so as to have a flat top surface 14, and both end sides of the top surface 14 are notched as shown in FIG. Furthermore, one end side of the top surface 14 is cut out to form a light guide groove 15 as an exit port. As shown in FIG. 2, the light guide groove 15 communicates with the internal space 13 and is formed so as to go obliquely upward with respect to the flat top surface 14.

  The lower lamp body 10 has a planar mounting plate 16 disposed in the internal space 13. A light source 18 is attached to the attachment plate 16 via an attachment member 17. The light source 18 includes a light emitting diode 18b mounted on the substrate 18a.

  The upper lamp body 9 is formed with a prism housing portion 20 for housing the prism 19. The prism accommodating portion 20 is communicated with the light guide groove 15. The prism 19 is made of, for example, tempered glass, is formed in a substantially trapezoidal shape, and is accommodated in the prism accommodating portion 20. The prism 19 is provided with a packing 21 having a frame shape made of silicone rubber. The prism 19 is liquid-tightly disposed in the light guide groove 15 and the internal space 13.

  The prism 19 performs light path regulation so that light from the light source 18 is incident and this light is emitted obliquely upward from the light guide groove 15. The light source 18 is disposed in the internal space 13 so as to face the incident surface of the prism 19 so that the emitted light is incident on the prism 19.

  The light source 18 is connected to a power supply device 22 disposed on the mounting plate 16 by a lead wire (not shown). The power supply device 22 is connected to a power receiving terminal 24 provided on the bottom surface 23 of the lower lamp body 10 by a lead wire (not shown). The power supply device 22 is configured to supply a predetermined current to the light source 18 when an external power supply is supplied to the power receiving terminal 24. Thereby, the light source 18 lights up and radiates | emits visible light.

  As shown in FIG. 1, the lamp body 2 has a recess 25 formed on the peripheral side of the upper surface 9 a of the upper lamp body 9. A stat bolt 26 is inserted from the adjustment ring 8 into a through hole (not shown) formed in the recess 25, and a nut 27 is tightened on the upper surface 9 a side of the upper lamp body 9. The lamp body 2 is accommodated and fixed in the adjustment ring 8 by a stat bolt 26 and a nut 27.

  In FIG. 2, the adjustment ring 8 includes first and second members 28 and 29 made of aluminum. The first member 28 is formed in a ring shape, and the second member 29 is formed in an annular seat. The first and second members 28 and 29 are integrated by four bolts 30. That is, as shown in FIG. 1, four recesses 31 are formed in the circumferential direction at 90 ° rotation intervals on the peripheral edge side of the first member 28. As shown in FIG. 2, an insertion hole (not shown) of the bolt 30 is formed in the recess 31, and a screw hole 32 of the bolt 30 is formed in the second member 29.

  The second member 29 is fixed to the lamp body 2 by the stat bolt 26 and the nut 27 as described above. Thereby, the lamp body 2 is fixed to the adjustment ring 8. The adjustment ring 8 is fixed to the spacer 7.

  The spacer 7 is made of aluminum, for example, and is divided into a ring body 33 and a ring body 34. The ring body 33 straddles the base 6. The ring body 34 is fitted to the ring body 33 from above, and is fixed to the ring body 33 by screws (not shown).

  The ring body 34 is fixed to the second member 29 of the adjustment ring 8 with bolts 35. That is, on the peripheral edge side of the second member 29, as shown in FIG. 1, the first member 28 is intermediate between the recesses 31 of the first member 28 and is rotated at 90 ° intervals in the circumferential direction. Four recesses 36 are provided. A long hole 37 through which the bolt 35 penetrates in the vertical direction is formed in the recess 36. As shown in FIG. 2, a screw hole 38 of a bolt 35 is formed in the ring body 34. The adjustment ring 8 and the lamp body 2 are attached to the spacer 7 by completely screwing the bolt 35 into the screw hole 38. At this time, the size of the spacer 7 is set so that the upper surface 8 a of the adjustment ring 8 is substantially located on the ground 3.

  The base 6 is made of, for example, aluminum, and is formed, for example, by casting into a bottomed box shape (substantially cylindrical) having an opening 39 on the upper end side 6a, a connection portion 40 on the side surface 6b, and an internal space 41 inside. Yes. And the base 6 has fixed the ring body 33 of the spacer 7 with the screw which is not shown in figure. That is, a through hole (not shown) through which a screw passes is formed in the recess 42 of the ring body 33, and a screw hole (not shown) corresponding to the through hole is formed on the upper end side 6 a of the base 6. By fixing the spacer 7 to the base 6, the base 6 is attached with the adjustment ring 8 and the lamp body 2. That is, the base 6 has the lamp body 2 attached to the opening 39 via the spacer 7 and the adjustment ring 8.

  The connection portion 40 formed on the side surface 6b of the base 6 is a through-hole into which the pipe 43 is inserted, and the pipe 43 is connected thereto. A power cable 44 is drawn from a later-described hand hole 48 through the pipe 43. A receptacle 45 is attached to the tip of the power cable 44.

  On the lower surface 23b of the bottom surface portion 23 of the lower lamp body 10 of the lamp body 2, a waterproof connector 46 in which the power receiving terminal 24 is disposed is provided. The plug-attached power wires 48 and 48 having a connector 47 attached to the waterproof connector 46 are accommodated in the base 6. The power lines 48 are electrically connected to the receptacle 45 of the power cable 44 and the waterproof connector 46 (power receiving terminal 24). Note that the receptacle 45, the connector 47, the power lines with plugs 48, 48 and the like are formed so as to be waterproof.

  The inner surface 6c of the base 6 is formed with alumite 6e so as not to be corroded by water, the antifreezing agent 5 or the like. That is, the inner surface 6 c of the base 6 is subjected to a corrosion treatment for the antifreezing agent 5.

  As shown in FIG. 3, the pipe 43 is connected to a hand hole 48 embedded in the ground 3. In the hand hole 48, a rubber transformer (rubber-covered insulating transformer) 49 is disposed. In the rubber transformer 49, the AC constant current output from the constant current power supply (CCR) 50 is input through the primary cables 51 and 52, and the converted AC constant current is input through the power cable (secondary cable) 44 to the embedded air traffic sign. Supply to lamp 1.

  Since the handhole 48 is open to the atmosphere or is not provided with a waterproof measure against rainwater or the like, water such as rainwater enters the inside and accumulates in the handhole 48. When the water surface rises up to the position where the pipe 43 is disposed, the water accumulated in the hand hole 48 enters the base 6 of the embedded air traffic light 1 through the pipe 43. Then, as the water level (water level) in the hand hole 48 rises, the water level in the base 6 rises.

  In FIG. 2, a mesh-structured box body 54 having a flange portion (attachment portion) 53 is disposed on the lower surface 23 b of the bottom surface portion 23 of the lower lamp body 10 of the lamp body 2. The box body 54 has a flange 53 attached to the lower surface 23b of the bottom surface 23 by a fixing means such as a mounting screw (not shown). The antifreezing agent 5 is disposed in the box body 54.

  The box 54 is not provided with the antifreezing agent 5, and when the water in the base 6 is solidified to form ice whose volume is expanded, the surface of the ice is the lower lamp of the lamp body 2. The water surface position before solidification when contacting the lower surface 23b of the body 10 is formed to be a height from the lower surface 23b. Thus, the antifreezing agent 5 is disposed in the vicinity of the lower surface 23 b side of the lower lamp body 10 of the lamp body 2.

As the antifreezing agent 5, for example, granular sodium acetate (CH ₃ CO ₂ Na) that dissolves easily in water and lowers the freezing point of water is used. And the antifreezing agent 5 is accommodated in the box 54 so that the concentration thereof becomes, for example, 25% or more when the embedded air traffic light 1 is filled with water and is completely dissolved.

The antifreezing agent 5 may also use chlorides such as sodium chloride (NaCl), calcium chloride (CaCl ₂ ), and magnesium chloride (MgCl ₂ ). However, since they easily corrode the base 6 and the lamp body 2 that are metals, it is desirable to use those that do not easily corrode metals.

  Further, the antifreezing agent 5 may be provided so as to be placed on the bottom surface 6 d of the base 6. That is, the antifreezing agent 5 only needs to be disposed in the base 6 so as to dissolve in the water that has entered the base 6.

  Next, the operation of this embodiment will be described.

  When the water level (water level) that has entered the handhole 48 rises to the position where the pipe 44 is disposed, the water enters the base 6 of the installation body 4 through the pipe 44. In the base 6, water accumulates so that the water level from the surface of the ground 3 in the hand hole 48 is substantially equal to the water level. As the water level in the hand hole 48 rises, the water level in the base 6 rises.

  When the water surface in the base 6 rises to the vicinity of the lower surface 23 b of the lower lamp body 10 of the lamp body 2, the antifreezing agent 5 disposed in the box body 54 is immersed in water. The antifreezing agent 5 is gradually dissolved in water. And if the water surface rises further, the part which the antifreezing agent 5 is immersed in water will increase, and the quantity which melt | dissolves in water will increase. In addition, the lamp body 2 has more portions that are immersed in water. Furthermore, the adjustment ring 8 is also immersed in water.

  The antifreezing agent 5 that has dissolved in water diffuses into the water, and the concentration in the water gradually increases as the amount of the antifreezing agent 5 increases. As the concentration increases, the freezing point of water gradually decreases. The freezing point of water becomes −25 ° C. when the concentration of the cryoprotectant 5 in water reaches a predetermined value (about 27%). Even if the ground 3 is frozen in a state where the freezing point of the water is lowered, the water of the installation body 4 is not frozen until at least −25 ° C. Accordingly, the volume of ice formed by the solidification of water expands and no pressure is applied to the lamp body 2 and the like, so that the lamp body 2 and the installation body 4 are prevented from being destroyed.

Then, sodium acetate as a cryoprotectant 5 (CH ₃ CO ₂ Na) is not easily corrode metals, with sodium acetate was dissolved into water, that such light body 2 and installation body 4 is corroded It is suppressed.

  Further, when the water level in the hand hole 48 decreases, the water level in the base 6 also decreases, and sodium acetate adheres to the inner surface 6 c of the base 6. Sodium acetate is difficult to corrode metals and the like, and the inner surface 6c of the base 6 is subjected to anticorrosion treatment with, for example, alumite 6e, so that corrosion prevention such as rusting on the base 6 is prevented. .

  As described above, at least until the temperature of the ground 3 is lowered to −25 ° C., the water that has entered the base 6 is not frozen and the lamp body 2 is not destroyed. Radiant light is emitted from the light emission groove 15 toward the side of the lamp body 2 through the prism 19.

  According to the present embodiment, the freezing agent 5 is dissolved in the water that has entered the base 6, so that the freezing point of water is lowered. Therefore, even if the temperature of the ground 3 on which the base 6 is embedded is lowered, It becomes difficult for the water in the base 6 to solidify, and thereby it is possible to suppress the destruction of the lamp body 2 and the installation body 4 due to the pressure from the ice formed by the solidification of the water that has entered the base 6. Has an effect.

  Further, since the antifreezing agent 5 is disposed in the vicinity of the lower surface 23b of the lamp body 2, the antifreezing agent 5 does not undesirably dissolve in the water that has entered the base 6, and prevents corrosion due to dissolution in water. It has the effect that adverse effects can be suppressed accordingly.

  Further, since the inner surface 6c of the base 6 is subjected to anticorrosion treatment with respect to the antifreezing agent 5 by, for example, anodizing 6e, water in which the antifreezing agent 5 is condensed at a high concentration accumulates in the base 6 for a long time. Even if it is a state, it has the effect that corrosion prevention of the base 6 can be suppressed.

  In the present embodiment, the embedded aerial beacon lamp 1 is described as an embedded illumination lamp. However, the present invention is not limited to this. For example, a guide light, a signboard, a sign, and the like installed on the ground 3 such as a road or a plaza. The present invention may be applied to a marker lamp that illuminates or an installation lamp that illuminates the surroundings.

  DESCRIPTION OF SYMBOLS 1 ... Implantable air marker lamp as an embedded illumination lamp, 2 ... Lamp body, 5 ... Antifreezing agent, 6 ... Base, 15 ... Light guide groove as an exit, 18 ... Light source, 39 ... Opening part

Claims (3)

A lamp body having a light source and an exit through which the emitted light of the light source is emitted on the upper surface side;
A base formed in a bottomed box shape having an opening, embedded in the ground, and attached to the opening;
An antifreezing agent disposed in the base so as to dissolve in the water that has entered the base;
An embedded illumination lamp characterized by comprising:   The antifreezing agent is disposed so as to dissolve into the water when the water surface that has entered the base and has accumulated in the base rises near the lower surface side of the lamp body. The embedded illumination lamp according to claim 1, wherein:   The embedded illumination lamp according to claim 1, wherein the inner surface of the base is subjected to anticorrosion treatment with respect to the antifreezing agent.

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