JP2009169726A - Lighting unit, traffic signal light lighting unit, traffic signal control unit, and antenna unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a signal lighting unit in which an antenna is integrated as a new technological means for dispensing with providing posts for antenna installation, and for preventing the fine sight of a road from being damaged. <P>SOLUTION: A signal lighting unit 1 is provided with an optical unit 2 and an antenna 4. The optical unit 2 is provided with an LED 7 and a cover member 9, having visible light permeability for covering the LED 7 in front. The antenna 4 is provided with antenna elements 11a and 11b, positioned in front of the front edge of the LED 7 and arranged in parallel as well as having a face along the forward and backward directions. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a lamp, and more particularly to a traffic signal lamp installed on a road, a traffic signal controller, and an antenna unit provided in the lamp.

In recent years, an Intelligent Transport System (ITS) has been proposed for the purpose of promoting traffic safety and preventing traffic accidents. In this ITS, a communication device (infrastructure device) is installed on the road, and the information emitted from the antenna of this communication device is received by the in-vehicle device of the vehicle traveling on the road, and this information is utilized, It is possible to improve the safety of traveling of the vehicle (see Patent Document 1).
When such road-to-vehicle communication is performed wirelessly, from the viewpoint of securing the prospect of wireless communication, an arm is extended from the column installed on the sidewalk or the like to the roadway side, and the antenna of the communication device is mounted on this arm. Further, when the line of sight can be secured without providing the arm, an antenna can be attached to the support column.

Japanese Patent No. 2806801

In order to install the antenna of the communication apparatus on the road, it is not economical to provide a new support for the antenna, and it is not preferable from the viewpoint of the aesthetics of the road.
Therefore, since vehicle detectors, optical beacon heads, and the like are installed on the road, it is conceivable that an antenna is provided alongside a column or arm to which these are attached. However, even in this case, it is not preferable in terms of aesthetics.

  Accordingly, it is an object of the present invention to provide a new technical means that can eliminate the need for an antenna support column and that does not impair the beauty of the road.

The lamp of the present invention includes an optical unit having a light emitter, and a balanced antenna incorporated in the optical unit,
The antenna includes an antenna element positioned in front of the front end of the light emitter and arranged in parallel with a surface along the front-rear direction.
According to this lamp, the antenna can be incorporated into the optical unit of the lamp and the antenna can be made inconspicuous. Furthermore, by incorporating the antenna into the optical unit of the lamp, a dedicated support for installing the antenna can be eliminated. Moreover, since the antenna element is disposed in front of the front end of the light emitter, desired antenna performance can be exhibited without the light emitter becoming an obstacle. Furthermore, since the antenna element is arranged in parallel with the surface along the front-rear direction, the light can be prevented from being blocked by the antenna element when the light emitter is viewed from the front (front). . Therefore, sufficient visibility of the light from the lamp can be ensured. Note that the “surface along the front-rear direction” here includes not only a real surface but also a virtual surface.

The optical unit has a cover member that has visible light permeability and covers the light emitter forwardly,
The antenna element is preferably disposed between the cover member and the front end of the light emitter. According to this configuration, the antenna element can be incorporated into the optical unit of the lamp as a range from the cover member to the front end of the light emitter, and the antenna can be made inconspicuous.

The optical unit has a plurality of the light emitters made of light emitting diodes,
It is preferable that the antenna element is disposed between the plurality of light emitting diodes when viewed from the front. With such a configuration, the light emitting diode and the antenna element are not overlapped when viewed from the front (front), and light from the light emitting diode can be reliably prevented from being blocked by the antenna element. The visibility of light can be further improved.

  The antenna element may be composed of a line patterned on an antenna substrate. Thereby, it becomes easy to make an antenna element into a predetermined shape. In this case, the antenna substrate and the antenna element can have a visible light transmission property. Thereby, for example, when the antenna element is arranged in the front-rear direction and parallel to the surface along the up-down direction, the visibility of the light of the lamp from the diagonally front left and right can be secured, and the antenna element is In the case of being arranged in parallel with the direction and the plane along the left-right direction, it is possible to ensure the visibility of the light of the lamp from obliquely forward and downward.

Preferably, the optical unit includes a light emitter substrate on which the light emitter is mounted on the front surface, and the antenna is supported by a support member disposed in front of the light emitter substrate.
It is conceivable that the antenna incorporated in the optical unit is supported by the light emitter substrate that constitutes the optical unit. However, when the antenna is supported by the light emitter substrate, a mounting portion such as a screw hole for attaching the antenna is provided on the substrate. It is necessary to form a complicated wiring that avoids the mounting portion. In addition, when the wiring cannot avoid the screw hole, the wiring must be connected by a jumper cable, which increases the number of parts and the manufacturing process, resulting in an increase in manufacturing cost. In the case of the present invention, since the antenna is supported by the support member disposed in front of the light emitter substrate, the above disadvantages can be avoided.

  The antenna may include a ground element disposed behind the support member and supported by the support member, and the antenna element may be attached to the ground element. Furthermore, in this case, it is preferable that an opening for penetrating the antenna element in the front-rear direction is formed in the support member. Accordingly, the antenna element attached to the ground element can be disposed in front of the support member, and the antenna element can be easily disposed in front of the front end of the light emitter.

  The antenna may be attached to the front surface of the support member. In this case, it is preferable that the support member has a hole through which the cable connected to the antenna passes. As a result, the cable can be connected to the antenna from the rear side of the support member.

The support member preferably has a function of preventing light incident from a predetermined direction outside the optical unit from being reflected by at least one of the light emitter substrate and the light emitter.
When the lamp is used as a traffic light lamp, the sun or the sun shining on the circuit board or light emitter is reflected to the ground, and the reflected light makes it difficult to see the lamp or is not lit. "Pseudo lighting" that appears to light up may occur.
The present invention provides the support member with a function of preventing light incident from a predetermined direction outside the optical unit (incident from obliquely above, such as the West or Asahi) from being reflected by the substrate or the light emitter. It is possible to prevent the lamp from becoming difficult to see and from causing false lighting. In other words, according to the present invention, by supporting the antenna using a member that prevents reflection of light, the structure can be simplified and the manufacturing cost can be reduced by sharing the parts.

The traffic signal lamp of the present invention comprises an optical unit having a light emitter, and a balanced antenna incorporated in the optical unit,
The antenna includes an antenna element positioned in front of the front end of the light emitter and arranged in parallel with a surface along the front-rear direction.
According to this traffic signal lamp, the antenna can be incorporated into the optical unit of the traffic signal lamp and the antenna can be made inconspicuous. Furthermore, by incorporating the antenna into the optical unit, a dedicated support for installing the antenna can be made unnecessary. Moreover, since the antenna element is located in front of the front end of the light emitter, desired antenna performance can be exhibited without the light emitter becoming an obstacle. Furthermore, since the antenna element is arranged in parallel with the surface along the front-rear direction, the light can be prevented from being blocked by the antenna element when the light emitter is viewed from the front (front). . Therefore, the visibility of the light of the traffic signal lamp can be sufficiently ensured.
In addition, the traffic signal lamp is installed on the road in consideration of visibility by the driver of the vehicle. For this reason, if this signal lamp is installed at a predetermined position on the road, a state of good visibility can be obtained in performing wireless communication between the antenna and the vehicle-mounted device.

  The traffic signal controller of the present invention is a traffic signal controller connected to the traffic signal lamp and for turning on and off the traffic signal lamp, and the road where the traffic signal lamp is installed via the antenna. Signal information relating to the current and future display of the traffic signal lamp is transmitted to a vehicle traveling on the vehicle.

The antenna unit of the present invention is an antenna unit for a lamp that is incorporated in an optical unit having a light emitter and a cover member that has visible light transparency and covers the light emitter forward.
A balanced antenna having an antenna element provided in a range from the cover member to the front end of the light emitter and parallel to a surface along the front-rear direction is provided.
According to the present invention, an antenna unit having a balanced antenna can be made inconspicuous by incorporating it into an optical unit of a lamp. Furthermore, since the antenna is incorporated into the optical unit of the lamp, a dedicated support for installing the antenna can be eliminated. Moreover, since the antenna element is located in front of the front end of the light emitter, desired antenna performance can be exhibited without the light emitter becoming an obstacle. Furthermore, since the antenna element is arranged in parallel with the surface along the front-rear direction, the light can be prevented from being blocked by the antenna element when the light emitter is viewed from the front (front). . Therefore, sufficient visibility of the light from the lamp can be ensured.

  According to the present invention, since the antenna is incorporated in the optical unit of the lamp unit, the support column for installing the antenna can be dispensed with and the aesthetic appearance of the road is not impaired.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a front view showing an embodiment of a lamp of the present invention. 1 is a traffic signal lamp 1 (hereinafter simply referred to as a signal lamp) installed on a road, and is for a vehicle.
A support column 40 is installed on the side of a road such as a sidewalk, and an arm 41 is provided so as to protrude from the support column 40 to the roadway side, and the signal lamp 1 is attached to the arm 41.

The signal lamp device 1 includes a plurality (three in the illustrated example) of optical units 2 and a housing 3 in which these optical units 2 are incorporated. The three optical units 2 have red, yellow, and blue lamp colors. A eaves (not shown) is attached to each optical unit 2.
A control device 5 that controls the signal lamp 1 is attached to the support column 40. Note that the installation structure of the signal lamp 1 may be other than that shown in the figure. Although not shown, the form of the support column 40 and the arm 41 may be different, and the signal lamp apparatus 1 is installed on a pedestrian bridge. It may be. Further, the control device 5 may be provided in the housing 3 of the signal lamp device 1.
The control device 5 that controls lighting of the signal lamp 1 can be configured to perform wireless communication control via the antenna 4 described later (or a device that performs wireless communication control is built in the same housing. But can be a separate device. When separate, it is preferable that the device for performing the wireless communication control is installed in the vicinity of the control device for controlling the lighting of the signal lamp 1 or the like (the same column 40).

  2, 3, and 4 are a perspective view, a front view, and a cross-sectional view of one optical unit 2. The optical unit 2 includes a light emitting diode 7 (hereinafter referred to as an LED) as a light emitter, an LED substrate 8 on which a plurality of LEDs 7 are mounted on a front surface 8a, a housing member 6, and a cover member 9. Further, the optical unit 2 of the present embodiment has an antireflection member (light shielding member) 10 for preventing the reflection of sunlight by the LED substrate 8 and the LED 7.

  The LED substrate 8 is formed in a circular plate shape. A wiring pattern is formed on the back surface of the LED substrate 8 and is connected to the terminal 37 of the LED 7. On the LED substrate 8, a plurality of LEDs 7 are arranged in a planar shape. The LED 7 has a lens portion 38, and an LED element (not shown) is provided in the lens portion 38.

  The accommodating member 6 is formed of a steel plate, aluminum, or a synthetic resin material, and has a dish shape having a bottom portion (bottom wall) 6a and a side portion (side wall) 6b erected from the periphery of the bottom portion 6a. Open forward. A step portion 6c is formed on the inner periphery of the side portion 6b on the opening side, and a cover member 9 is detachably attached to the step portion 6c. Thereby, a housing space portion S is formed between the housing member 6 and the cover member 9, and the LED 7 and the LED substrate 8 are housed in the housing space portion S. The LED substrate 8 is fixed to the housing member 6 via the antireflection member 10. Of the accommodation space S, the front space portion S1 is ahead of the LED board 8, and the rear space portion S2 is behind the LED board 8.

  The cover member 9 is a lens made of glass or resin, has visible light transparency (transparent to visible light), and covers the plurality of LEDs 7 at the front. The rear surface (back surface) 9a of the cover member 9 is a concave curved surface, and the front surface 9b is a convex surface. However, if the signal lamp 1 is an LED lamp, the cover member 9 may be a flat plate made of glass or the like in which the rear surface 9a and the front surface 9b are flat surfaces instead of the lens. In this optical unit 2, the front is the light projecting side (the cover member 9 side), and the rear is the bottom 6 a side of the housing member 6.

  The antireflection member 10 restricts the sunlight such as the sun and the sun from entering the LED substrate 8 and the reflecting mirror 7a (see FIG. 6) in the LED 7, thereby making the LED substrate 8 and the reflecting mirror 7a. This prevents the signal lamp 1 from being difficult to see due to reflection, or the occurrence of “pseudo lighting” that appears as if the signal lamp 1 is not lit. The antireflection member 10 has a function as a support member that supports the LED substrate 8 and the antenna 4 described later.

The antireflection member 10 is formed of a synthetic resin material that is an insulating member, and is disposed in front of the LED substrate 8 as shown in FIG. 4. The antireflection member 10 includes a plate-like portion 10 a formed in a circular plate shape (planar shape), and the plate-like portion 10 a is disposed behind the front end 39 of the LED 7. In the plate-like portion 10a, a plurality of insertion holes 10b for inserting the LEDs 7 are formed corresponding to the arrangement of the LEDs 7. The insertion holes 10b are arranged radially outward in the radial direction.
The plate-like portion 10a mainly prevents sunlight from directly hitting the LED substrate 8. The antireflection member 10 is formed of a black synthetic resin material, or at least the front surface of the plate-like portion 10a is painted black so that the reflection of sunlight is prevented. The antireflection member 10 is configured such that the outer peripheral portion of the plate-like portion 10a is fitted into the step portion 6c of the containing member 6, and a not-shown claw formed on the step portion 6c is engaged with the plate-like portion 10a. It is fixed to.

  A boss portion 10c is formed on the rear surface of the plate-like portion 10a so as to protrude rearward. The LED substrate 8 is fixed to the plate-like portion 10a by screws 25 screwed into the screw holes of the boss portion 10c. The front surface 8a of the LED substrate 8 is in contact with the front end surface of the boss portion 10c, and an interval corresponding to the height of the boss portion 10c is provided between the plate-like portion 10a and the LED substrate 8.

  FIG. 5 is a rear (rear) view of the antireflection member 10. On the rear surface of the plate-like portion 10a of the antireflection member 10, circular ribs 10d and radial ribs 10e are integrally formed. The four boss portions 10c are integrally formed on the rear surface of the plate-like portion 10a at equal intervals in the circumferential direction. Further, four boss portions 10f are integrally formed on the rear surface of the plate-like portion 10a at equal intervals in the circumferential direction at positions shifted from the boss portion 10c in the circumferential direction and the radial direction. The boss portion 10f is an attachment portion for attaching a ground element 12 described later. Further, the boss portion 10f is formed lower than the boss portion 10c and slightly higher than the ribs 10d and 10e. A cylindrical portion 10g that protrudes rearward is provided around each insertion hole 10b, and the cylindrical portion 10g is formed at the same height as or slightly lower than the boss portion 10f.

As shown in FIGS. 2 to 4, a flange 10 h is formed on the upper edge of the insertion hole 10 b of the antireflection member 10 so as to protrude forward. As shown in FIG. 6, the eaves part 10 h prevents the sunlight O shining from diagonally above, such as the West or Asahi, from entering the reflecting mirror 7 a of the LED 7. Therefore, the sunlight O can be suitably prevented from being reflected by the reflecting mirror 7a. The front end of the collar portion 10 h protrudes from the front end of the LED 7. The cylindrical portion 10 g of the antireflection member 10 surrounds the outer peripheral surface of the LED 7 and holds the posture of the LED 7.
The antireflection member 10 may have only a function of preventing the reflection of sunlight by the LED substrate 8, or may have only a function of preventing the reflection of sunlight by the LED 7.

As shown in FIGS. 2 to 4, an antenna 4 is incorporated in the optical unit 2. Specifically, the antenna 4 is disposed between the cover member 9 and the LED substrate 8 in the accommodation space S. The antenna 4 includes an antenna substrate 16, and antenna elements 11 a and 11 b are provided on the antenna substrate 16. Further, a strip line 31 is further formed on the antenna substrate 16, and the strip line 31 is also incorporated in the optical unit 2.
The antenna substrate 16 is made of a rectangular flat plate and is made of a dielectric material such as glass epoxy. The antenna substrate 16 has a thickness of about 1 mm.

  The antenna 4 is a balanced type, and what is shown is a dipole antenna fed by balanced two wires. As shown in FIG. 8A, the antenna 4 includes a dipole portion 11, a pair of balanced feed line portions 32 a and 32 b, and a ground element 12. The dipole part 11 and the balanced feed line parts 32a and 32b are formed by lines patterned as a thin film conductor on one surface side of the antenna substrate 16. The dipole part 11 includes a pair of upper and lower antenna elements 11a and 11b arranged so as to extend in the vertical direction. The pair of balanced power supply line portions 32a and 32b extend in the front-rear direction (the front is indicated by an arrow F) and are arranged in parallel to each other. One antenna element 11a is connected to the front end of one balanced feed line portion 32a so as to be orthogonal. The other antenna element 11b is connected to the front end of the other balanced feed line portion 32b so as to be orthogonal.

The strip line 31 is a line patterned as a thin film conductor on the other surface side of the antenna substrate 16 (the surface opposite to the dipole portion 11 and the balanced feed line portions 32a and 32b). The strip line 31 is formed to extend linearly in the front-rear direction at a position on the other surface side of the antenna substrate 16 and on the back side of the balanced feed line portion 32a, and between the antenna elements 11a and 11b of the dipole portion 11. The direction is reversed in a U-shape at the center of the antenna substrate 16 and linearly extends in the front-rear direction at a position on the other surface side of the antenna substrate 16 and on the back side of the balanced feed line portion 32b.
The material of the dipole part 11, the balanced power supply line parts 32a and 32b, and the strip line 31 is preferably a material having conductivity and high conductivity, such as a copper foil such as copper or brass, or a metal foil made of aluminum or the like. Preferably, iron, nickel or other metal foil can be used.

  As a method for forming the antenna elements 11a and 11b, the balanced feed line portions 32a and 32b, and the strip line 31 on the antenna substrate 16, there are the following methods. The antenna elements 11a and 11b, the balanced feed line portions 32a and 32b, and the strip line 31 are each formed as a thin film conductor, and each is attached to the antenna substrate 16. In this case, the antenna elements 11a and 11b, the balanced feeder lines 32a and 32b, and the strip line 31 are bonded to the antenna substrate 16 with an adhesive member (adhesive tape). Alternatively, the antenna elements 11a and 11b, the balanced feed line portions 32a and 32b, and the strip line 31 may be formed by performing metal vapor deposition on the antenna substrate 16. Alternatively, the antenna elements 11a and 11b, the balanced feed line portions 32a and 32b, and the strip line 31 may be formed on the antenna substrate 16 by printing. For example, the antenna elements 11a and 11b, the balanced feeder lines 32a and 32b, and the strip line 31 are formed on the antenna substrate 16 having a copper foil on the surface in the same process as that for manufacturing a general printed wiring board. These antenna elements 11a, 11b, 32a, 32b, 31 may be formed by printing a resist pattern and performing etching. Alternatively, antenna elements 11a and 11b, balanced feed line portions 32a and 32b, and strip line 31 may be formed by performing metal plating on antenna substrate 16.

  As shown in FIGS. 3 and 4, the ground element 12 is formed in a circular plate shape (planar shape), and is attached to the antireflection member 10 on the front surface 8 a side of the LED substrate 8. More specifically, as shown in FIG. 6, a boss portion 10f is formed on the rear surface of the antireflection member 10, and the ground element 12 is screwed by a screw 26 screwed into the screw hole of the boss portion 10f from the rear. It is fixed. The front surface of the ground element 12 is in contact with the front end surface of the boss part 10 f, and the boss part 10 f functions as a spacer that sets the distance between the ground element 12 and the plate-like part 10 a of the antireflection member 10. Further, as shown in FIG. 5, when the boss portion 10f, the ribs 10d, 10e, and the cylindrical portion 10g have the same height, the ribs 10d, 10e and the cylindrical portion 10g also function as spacers. The ground element may be rectangular or polygonal, and may be any shape as long as it can be stored in the lamp.

  As shown in FIG. 4, the ground element 12 is fixed only by the antireflection member 10, and is provided at a position between the LED substrate 8 and the front end 39 of the LED 7 in the front-rear direction. The ground element 12 is disposed between the LED substrate 8 and the plate-like portion 10a of the antireflection member 10 in parallel with the LED substrate 8 and the plate-like portion 10a. A plurality of holes 14 are formed in the ground element 12 as openings through which the LEDs 7 (lead wires of the LEDs 7) are inserted. The arrangement of the holes 14 is matched with the arrangement of the LEDs 7, and the ground element 12 has a mesh structure. In other words, the network structure here includes a structure in which several holes are formed in a flat plate such as briquette. In addition, although the hole which penetrates the boss | hub part 10c of the antireflection member 10 is formed in the ground element 12, when the said boss | hub part 10c is arrange | positioned at the outer peripheral side of the ground element 12, the said hole is unnecessary. It becomes.

  The ground element 12 is formed from a metal plate. The material of the ground element 12 is preferably a material having conductivity and high conductivity. For example, a copper alloy such as copper or brass, or aluminum is preferable, and iron, nickel, or other metal may be used. Moreover, since a high-frequency current flows on the surface, the plate member may be metal-deposited or metal-plated (gold or silver plating) (not shown).

  An antenna substrate 16 is attached to the front surface of the ground element 12 in an upright state. Specifically, as shown in FIGS. 8A and 8B, the antenna substrate 16 is fixed to the front surface (metal surface) of the ground element 12 via two attachments 33. The fixture is made of metal and is formed in an L shape. One side of the fixture is fixed to the ground element 12 by a fastener 36 such as a mounting screw and a nut, and the other side is balanced feed line portions 32 a and 32 b of the antenna substrate 16. It is fixed by soldering or the like while in contact with Therefore, the ground element 12 and the balanced feeder lines 32 a and 32 b are connected via the fixture 33. Here, both the ground element 12 and the balanced feeder lines 32 a and 32 b function as a ground for the strip line 31. The strip line 31, the balanced power supply line portions 32a and 32b, and the ground element 12 constitute a balun (balanced unbalanced conversion portion). Note that the attachment 33 can be attached to both the antenna substrate 16 and the ground element 12 using the fastener 36, or can be attached by soldering.

  The ground element 12 is disposed perpendicular to the front-rear direction (light projecting direction of the LED 7), and the antenna substrate 16 is attached to the ground element 12 in an upright state. The antenna elements 11a and 11b, the balanced feed line portions 32a and 32b, and the strip line 31 are along the front-rear direction (parallel to the surface (virtual surface) along the front-rear direction), similarly to the plate surface of the antenna substrate 16. Arranged).

As shown in FIG. 4, a terminal part 19 for connecting the coaxial cable 15 for the antenna 4 is attached to the housing member 6 (bottom part 6 a). The terminal part 19 extends from the control device 5 of FIG. 1. A coaxial cable 15 can be connected. A coaxial cable 15 a extending from the terminal portion 19 to the rear space portion S <b> 2 is connected to the antenna 4. As shown in FIGS. 8A and 8B, the coaxial cable 15a includes an inner conductor (center conductor) 15b, an insulator 15c, an outer conductor 15d, and a covering portion 15e. The conductor 15b is connected to the strip line 31, and the outer conductor 15d is connected to the ground element 12 (balanced feed line portion 32b). The inner and outer conductors 15b and 15d and each part can be connected and fixed by soldering, but a method other than soldering may be used.
A power cable (not shown) for the LED 7 extending from the control device 5 in FIG. 1 is connected to the LED substrate 8 via a terminal portion (not shown) attached to the bottom 6 a of the housing member 6. Yes.

  As shown in FIG. 4, the antenna substrate 16 protrudes forward from the ground element 12 and penetrates the plate-like portion 10 a of the antireflection member 10. Specifically, the antireflection member 10 has a slit (opening) 35 through which the antenna substrate 16 penetrates. The antenna substrate 16 penetrates the slit 35 more than the antireflection member 10. Projects forward. As shown in FIG. 3, the slit 35 is formed long along the vertical direction, and therefore the antenna substrate 16 is also arranged along the vertical direction.

The slit 35 is formed between the plurality of LEDs 7. Since the LEDs 7 are arranged substantially radially outward from the center of the front of the optical unit 2, the plurality of LEDs 7 also extend linearly along the radial direction. Therefore, the slit 35 can also be formed linearly in a direction (vertical direction) along the radial direction.
As shown in FIG. 4, the antenna elements 11 a and 11 b of the antenna substrate 16 penetrating the slit 35 are arranged in front of the front end 39 of the LED 7 and behind the cover member 9. That is, it is arranged in the range A.

According to the above embodiment, the antenna 4 (including the strip line 31) is incorporated in the signal lamp device 1. And the antenna elements 11a and 11b of the antenna 4 are arranged in front of the front end 39 of the LED 7, thereby preventing the LED board 8 and the LED 7 from interfering with transmission / reception of radio waves. Further, since the antenna substrate 16 and the antenna elements 11a and 11b are arranged along the front-rear direction, when the optical unit 2 is viewed from the front (front), the light of the LED 7 is transmitted to the antenna substrate 16 and the antenna element. 11a and 11b are not obstructed, and the light visibility of the signal lamp 1 is hardly impaired.
Further, since the antenna elements 11a and 11b are arranged along the vertical direction, the light from the LED 7 is hardly blocked by the antenna elements 11a and 11b even when looking up at the signal lamp 1 obliquely upward from the ground. Absent.

  As shown in FIG. 4, the ground element 12 and the LED 7 overlap with each other in the front-rear direction, but the ground element 12 is formed with a plurality of holes 14 as openings through which the LED 7 (the terminal 37 of the LED 7) is inserted. Therefore, the LED 7 can be inserted into the hole 14 of the ground element 12 so that the ground element 12 does not interfere with the LED 7, and the ground element 12 can be installed at a predetermined position. As shown in the figure, the opening 7 formed in the ground element 12 can be arranged such that the LED 7 can be disposed so as not to interfere with the element by making a hole 14 in the element. However, without providing a hole, for example, the conductor portion (conductor portion) of the element is arranged in a meandering manner (the conductor portion is arranged so as to be drawn in one stroke), and the LED 7 is arranged so as not to interfere with the element. You can also

Since the slit 35 is formed in the antireflection member 10, the antenna substrate 16 erected on the ground element 12 behind the antireflection member 10 is projected to the front side of the antireflection member 10, so that the antenna elements 11 a and 11 b are provided. Can be arranged in front of the front end of the LED 7.
Since the antenna 4 (the ground element 12 and the antenna substrate 16) is attached to and supported by the antireflection member 10, it is not necessary to provide an attachment portion such as a screw hole for attaching the antenna 4 to the LED substrate 8. . Therefore, the circuit wiring (wiring pattern portion) of the LED substrate 8 is not complicated to provide the mounting portion, and the wiring design restriction is not increased. In addition, since a jumper cable or the like is not required to provide the mounting portion, the number of parts and the manufacturing process are not increased, and an increase in manufacturing cost can be suppressed.

  In the present embodiment, the LED substrate 8 is also attached to the antireflection member 10. Therefore, the antenna 4 and the LED substrate 8 are attached to the antireflection member 10, and these are integrated. Therefore, these integrated components can be configured as one unit. If the antireflection member 10 is attached to the housing member 6, the entire unit can be attached to the housing member 6, so that the unit can be easily attached to the housing member 6. Since it is sufficient to provide the housing member 6 with an attachment portion for the antireflection member 10, the structure can be simplified. However, the accommodating member 6 may be provided with a member for supporting components other than the antireflection member 10.

  The antireflection member 10 may be structured as shown in FIG. The antireflection member 10 is not provided with a flange portion, and the plate-like portion 10a of the antireflection member 10 is substantially aligned with the front end 39 of the LED 7 (the front end 39 of the LED 7 is within the thickness of the plate-like portion 10a). Are included). Further, the center of the insertion hole 10 b is disposed slightly below the center of the LED 7. With such a structure, it is possible to suitably prevent the sunlight O that shines obliquely from above even without a collar from being reflected by the reflecting mirror 7a. As shown in FIG. 7, the configuration in which the plate-like portion 10 a substantially coincides with the front end 39 of the LED 7 is also included when the plate-like portion 10 a is behind the front end 39 of the LED 7, as in FIG. 6. . Although not shown, the plate-like portion 10a can be disposed in front of the front end 39 of the LED 7.

  Further, a spacer 28 separate from the antireflection member 10 is provided on the rear surface of the antireflection member 10 instead of the boss 10 f as shown in FIG. 4, and a bolt 29 and a nut 30 penetrating the spacer 28 are provided. A ground element 12 is fixed to the plate-like portion 10a.

  As described above, when the antenna elements 11a and 11b are arranged in front of the front end of the LED 7 and are arranged along the front-rear direction and the vertical direction, the visibility of the signal lamp 1 from the front can be sufficiently secured. it can. However, when the signal lamp 1 is viewed obliquely from the left and right, some of the LEDs 7 are hidden by the antenna substrate 16, and the visibility of the signal lamp 1 from the same direction may be reduced (see FIG. 2). In order to prevent this, the antenna substrate 16 and the lines 11a, 11b, 32a, 32b, and 31 formed on the antenna substrate 16 can be configured to have visible light transparency (transparent to visible light). is there.

  For example, the antenna substrate 16 is made of a material having visible light transparency such as glass, polycarbonate, acrylic, or polyethylene terephthalate. The antenna elements 11a and 11b, balanced feed line portions 32a and 32b, and the strip line 31 on the antenna substrate 16 have a mesh structure, so that visible light transparency can be provided.

In order to make the antenna elements 11a and 11b, the balanced feed line portions 32a and 32b, and the strip line 31 have a mesh structure, a mesh made of a metal film (metal thin film) may be formed on one surface and the other surface of the antenna substrate 16. it can. As specific examples of the antenna elements 11a and 11b, the balanced feed line portions 32a and 32b, and the strip line 31 by the mesh of the metal film, for example, the surface of the antenna substrate 16 has a line width of 10 μm and a pitch (mesh spacing). ) May be formed as a fine mesh composed of a conductive wire part having a thickness of 100 μm. When a fine mesh is formed on the antenna substrate 16 as described above, the line width is preferably 1 μm or more and 50 μm or less, and the pitch is preferably 50 μm or more and 1000 μm or less, and further, the line width is 5 μm or more and 50 μm. The pitch is preferably 100 μm or more and 1000 μm or less.
The mesh shape is not limited to a quadrangular shape, but may be a triangular shape or a honeycomb shape, or may be a radial shape (spider web shape) or the like as a whole.

  Further, in order to make the antenna elements 11a and 11b, the balanced power supply line portions 32a and 32b, and the strip line 31 have visible light transparency, these are made into a thin film conductor (thin film metal) having visible light transparency. Can do. Then, by forming this thin film conductor on the antenna substrate 16, the antenna elements 11a and 11b, the balanced feed line portions 32a and 32b, and the strip line 31 can be formed thin and in a predetermined shape. In this case, the thickness of the thin film conductor is preferably 1 μm or more and 100 μm or less, and thereby has visible light permeability.

FIG. 9 is a front view showing another embodiment of the signal lamp with a built-in antenna in which the antenna 4 is built in the optical unit 2. The difference between this embodiment and the embodiment shown in FIG. 3 is that the antenna substrate 16 (antenna elements 11a and 11b) is arranged along the front-rear direction and the left-right direction. The configuration is the same.
In the case of this embodiment, the visibility of the signal lamp device 1 from the front and diagonally front left and right can be sufficiently ensured. However, when the signal lamp 1 is viewed from the top and bottom diagonally, some of the LEDs 7 are hidden by the antenna substrate 16, and the visibility of the signal lamp 1 from the same direction may be lowered. In order to improve the visibility from the same direction, the antenna substrate 16 and the lines 11a, 11b, 32a, 32b, 31 formed on the antenna substrate 16 may have visible light transparency as described above.

  FIG. 10 is a front view showing another embodiment of the signal lamp with a built-in antenna in which the antenna 4 is built in the optical unit 2. The difference between this embodiment and the embodiment shown in FIG. 3 is that two antenna substrates 16 of the antenna 4 are provided, and the two antenna substrates 16 are arranged in a cross shape and orthogonal to each other. . In this case, the antenna elements 11a and 11b, the balanced feeder lines 32a and 32b, and the strip element 31 formed on each antenna substrate 16 are arranged so as not to contact each other. As a result, it is possible to configure the dual-polarized antenna 4 having a 90 ° angle shift (orthogonal). In this case, since the two antenna substrates 16 are arranged along the front-rear direction, the visibility of the signal lamp 1 from the front is hardly hindered. Note that the two antenna substrates 16 may be arranged in an X shape by being inclined by 45 °. As an example of using two (or three or more) antenna substrates 16, the two antenna substrates 16 may be arranged side by side without crossing, arranged in parallel, or arranged in a T-shape or L-shape. It is also possible to do. Further, by inputting signals having the same amplitude (same intensity) and 90 ° phase shifts to the two polarized antennas 4 shifted (orthogonal) by 90 ° angles, the two antennas 4 are turned into one circle. It can also be used as a polarized antenna 4.

FIG. 11 is a side view showing another embodiment of the signal lamp with a built-in antenna in which the antenna 4 is built in the optical unit 2. In this embodiment, the antenna 4 does not include the ground element 12, the antenna substrate 16 is formed with a portion 34 that short-circuits the two balanced feeder portions 32 a and 32 b, and the strip line 31 is coaxial. The central conductor 15b of the cable 15 is connected, and the outer conductor 15d of the coaxial cable 15a is connected to the balanced feeder lines 32a, 32b or the portion 34. Therefore, the balanced feeder lines 32 a and 32 b and the part 34 function as the ground of the strip line 31. The antenna substrate 16 is directly fixed to the front surface of the antireflection member 10 via a fixture 33 ′. In the case of this embodiment, the antireflection member 10 is formed with a hole through which the coaxial cable 15a passes.
In the present embodiment, the configuration of the antenna 4 is compact and easy to incorporate in the optical unit 2, and the antireflection member 10 does not require a slit for penetrating the antenna substrate 16, so the structure is simple. . However, in the antenna 4 having this structure, a slit may be formed in the antireflection member 10 and a part of the antenna substrate 16 may be inserted into the slit, and then the antenna substrate 16 may be fixed to the antireflection member 10. .

  In addition, when the antireflection member 10 is formed of a material having high conductivity (for example, copper alloy such as copper and brass, aluminum is preferable, iron, nickel, or other metal), the antireflection member 10 is used. Can be used as the ground element 12, and the antenna substrate 16 having the configuration shown in FIG. In this way, by providing the antireflection member 10 with the function as the ground element 12, the number of components constituting the antenna 4 or the optical unit 2 is reduced, thereby reducing the cost, simplifying the structure, and reducing the size of the housing member 6 ( Thinning) is possible. Since the antireflection member 10 does not require a slit for penetrating the antenna substrate 16, the structure is simplified.

  As another example for using the antireflection member 10 as the ground element 12, the ground element 12 can be formed by applying metal deposition or metal plating to the front surface of the antireflection member 10 formed of a synthetic resin material. . Further, only a portion that functions as the ground element 12 (for example, the inner peripheral side of the antireflection member 10) is formed of metal, and a portion that functions only as the antireflection member 10 (for example, the outer peripheral side) is formed of a synthetic resin material. You can also. In these cases, the weight can be suppressed as compared with the case where the entire antireflection member 10 is made of metal.

  According to each of the above embodiments, the antenna 4 is incorporated in the optical unit 2 of the signal lamp 1. 1 has three optical units 2, and an antenna 4 is incorporated in each optical unit 2. Thereby, the antenna 4 can be installed in the signal lamp 1 without making it conspicuous, and the aesthetic appearance of the road is not impaired. And since the antenna 4 is incorporated in the optical unit 2 of the signal lamp device 1, a dedicated column for installing the antenna can be dispensed with. Further, since the antenna 4 is not in an exposed state (a protruding state), it is necessary to additionally consider the wind load received by the antenna 4 in the design of the support column 40 and the arm 41 (FIG. 1) for attaching the signal lamp 1. There is no. Further, there is no need to additionally consider rust prevention and dust prevention for the antenna 4.

  Further, since the traffic signal lamp 1 is installed on the road in consideration of the visibility by the driver of the vehicle, the antenna 4 and the vehicle can be installed by installing the signal lamp of each embodiment at a predetermined position on the road. When performing wireless communication with the in-vehicle device, it is possible to naturally get a good view. Therefore, the antenna 4 incorporated in the optical unit 2 can be used in an intelligent road traffic system (ITS) that performs wireless communication between road vehicles, and a good communication state can be obtained.

The control device 5 (traffic signal controller) for controlling the traffic signal lamp 1 described in the present embodiment is applied to a vehicle traveling on the road where the traffic signal lamp 1 is installed or a nearby road via the antenna 4. On the other hand, the signal information regarding the present and future displays of the traffic signal lamp 1 can be provided.
The signal information refers to information related to the current or future signal lamp color displayed by the traffic signal lamp 1, and includes information related to the scheduled duration of display of each signal lamp color, the display order, and the like.
For example, the currently displayed lamp color is a blue light and its scheduled duration is 5 seconds, the next displayed lamp color is a yellow signal and its scheduled duration is 8 seconds, and the next displayed lamp color. It is preferable to include information such as a right turn blue arrow light whose estimated duration is 5 to 10 seconds in a predetermined format. Note that only the currently displayed lamp color and its duration may be provided, or information for one cycle may be provided collectively. In addition to these pieces of information, parameter information related to the control, information on a time zone in which the control is performed, and the like may be included at the point where the point sensitive control is performed.

Then, the vehicle-side computer on the vehicle side that has received the signal information estimates the time required to reach the stop line from the distance to the stop line and the traveling speed, acceleration, etc. of the vehicle, and after the required time has elapsed. Can be estimated. For example, even if a green signal is displayed at the present time, if the signal light color is predicted to be a red signal when arriving at the stop line, the in-vehicle computer is safely stopped before the stop line. Can be controlled. Conversely, if it can be determined that the vehicle can safely pass through the intersection unless the vehicle is decelerated, control may be performed to maintain the speed.
Further, the in-vehicle computer may perform not only the control by the in-vehicle device but also the operation for assisting the driving operation of the driver such as brake assist.
The in-vehicle computer may notify the vehicle occupant of the determination result by voice or image information. For example, an audio message such as “The signal changes soon and should be stopped” may be emitted to the driver, or may be displayed on the screen of the head-up display or the navigation device with characters or symbols.

  The lamp of the present invention is not limited to the above embodiment. For example, the signal lamp may be for pedestrians as well as for vehicles. Further, the light emitter included in the signal lamp device may be a light bulb other than the LED. In the above-described embodiment, the antenna elements 11a and 11b and the balanced feed line portions 32a and 32b are formed on the antenna substrate 16. However, the antenna elements 11a and 11b and the antenna elements 11a and 11b are not provided without the antenna substrate 16. The balanced power supply line portions 32a and 32b can be made of sheet metal or can be formed of a wire (electric wire). The balanced antenna may be other than the dipole antenna or may be a loop antenna. Further, the present invention may be an illuminating lamp for road illumination other than a signal lamp. In this case, there are mercury lamps and sodium lamps as light emitters.

It is a front view which shows one Embodiment of the lamp device of this invention. It is a perspective view of an optical unit. It is a front view of an optical unit. It is sectional drawing of an optical unit. It is a rear view of an antireflection member. It is sectional drawing which expands and shows the attachment part of the ground element with respect to an antireflection member. It is sectional drawing which expands and shows another example of the reflection prevention member of another form, and another example of the attachment part of the ground element with respect to this reflection member. (A) is an enlarged side view of the antenna substrate, and (b) is a bottom view thereof. It is a front view which shows the optical unit and antenna of another embodiment. It is a front view which shows the optical unit and antenna of another embodiment. It is a side view which expands and shows the board | substrate for antennas of another embodiment.

Explanation of symbols

1 Signal lamp (lamp)
2 Optical unit 4 Antenna 5 Control device (traffic signal controller)
7 LED (light emitter)
8 LED substrate (substrate for light emitter)
9 Cover member 10 Antireflection member (support member)
11a, 11b Antenna element 12 Ground element 16 Antenna substrate 35 Opening

Claims (13)

An optical unit having a light emitter, and a balanced antenna incorporated in the optical unit,
The said antenna has the antenna element located ahead of the front end of the said light-emitting body, and arrange | positioned in parallel with the surface along the front-back direction, The lamp device characterized by the above-mentioned. The optical unit has a cover member that has visible light permeability and covers the light emitter at the front,
The lamp according to claim 1, wherein the antenna element is disposed between the cover member and a front end of the light emitter. The optical unit has a plurality of the light emitters made of light emitting diodes,
The lamp device according to claim 1, wherein the antenna element is disposed corresponding to the plurality of light emitting diodes when viewed from the front.   The lamp device according to any one of claims 1 to 3, wherein the antenna element includes a line patterned on an antenna substrate.   The lamp device according to claim 4, wherein the antenna substrate and the antenna element have visible light transmittance. The optical unit includes a light emitter substrate on which the light emitter is mounted on the front surface,
The lamp according to claim 1, wherein the antenna is supported by a support member disposed in front of the light emitter substrate.   The antenna includes a ground element disposed behind the support member and supported by the support member, the antenna element is attached to the ground element, and the antenna element is attached to the support member in the front-rear direction. The lamp according to claim 6, wherein an opening that penetrates the lamp is formed.   The lamp according to claim 6, wherein the antenna is attached to a front surface of the support member.   The lamp according to claim 8, wherein a hole through which a cable connected to the antenna passes is formed in the support member.   The support member has a function of preventing light incident from a predetermined direction outside the optical unit from being reflected by at least one of the light emitter substrate and the light emitter. The lamp according to one. An optical unit having a light emitter, and a balanced antenna incorporated in the optical unit,
The traffic signal lamp according to claim 1, wherein the antenna has an antenna element positioned in front of the front end of the light emitter and parallel to a plane along the front-rear direction. A traffic signal controller connected to the traffic signal lamp according to claim 11 for turning on and off the traffic signal lamp,
Via the antenna, it is configured to transmit signal information related to the display of the current and future traffic signal lamps to a vehicle traveling on a road where the traffic signal lamps are installed. Traffic signal control machine. An antenna unit for a lamp that is incorporated in an optical unit having a light emitter and a cover member that has visible light permeability and covers the light emitter at the front,
An antenna unit for a lamp, comprising a balanced antenna having an antenna element arranged in parallel with a surface along the front-rear direction in a range from the cover member to the front end of the light emitter.

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