JP2011159429A - Lighting system, aircraft warning light and system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lighting system lighting even when a light source or power source is not provided near while further reducing the cost, and also to provide an aircraft warning light and system. <P>SOLUTION: The lighting system 10 inputs light transferred from an input terminal portion 11 connected to an upstream-side transfer path 201, allows passage of light other than a specified wavelength of the input light and outputs it to a downstream-side transmission path 202 through an output terminal portion 13. The lighting system 10 converts the wavelength of the light of the specific wavelength which has not passed, and reflects and diffuses the converted light to emit light. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a lighting device, an aircraft obstacle light, and a system.

  Conventionally, many lighting devices, aviation obstacle lights, etc. are installed in buildings, power transmission line towers, etc., and are systematized and managed collectively for monitoring and maintenance. Patent documents 1 and patent documents 2 are known as a system which manages such an illuminating device, an aviation obstacle light, etc. collectively.

  Patent Document 1 discloses a technology of an illumination control system in which a terminal is connected to a transmission line of a central control device to collectively manage lighting devices and aviation obstacle lights in a building. In addition, in Patent Literature 2, in the aviation obstruction light on the transmission line tower, as a risk avoidance of replacing the light source in the event of a light source failure, the light source is arranged in the lower part of the transmission tower, and the light emitted from the lower light source is A technique is disclosed in which light is emitted from the top of a power transmission tower guided by an optical fiber for a light source and having a high ground height.

JP 2002-110367 A JP 2008-83832 A

  However, in the technique disclosed in Patent Document 1, the aviation obstruction light is for buildings and requires an aviation obstruction light power source. And since the transmission line used for this technology is for the collective monitoring control signal of the lighting in the building and the aviation obstacle light, the power supply (storage battery) of the aviation obstacle light on the power transmission tower with long transmission distance ) Not suitable for supply or collective monitoring control.

  Moreover, although the technique disclosed by patent document 2 is targeting the aviation obstruction light on each power transmission tower, it is necessary to arrange | position a light source, a power source, etc. per 1 or 2 power transmission towers. Therefore, in the present situation where there is almost no distribution line (low-voltage power line for light source) in the vicinity of the power transmission tower, the area where the target aviation obstacle light is installed is limited. Furthermore, if a light source, a power source, etc. are provided for each power transmission tower, the equipment construction cost and the operation cost are high and not energy saving.

  Therefore, there is a demand for an illuminating device that can illuminate without having a light source or a power supply nearby, and can further reduce the cost compared to the related art.

  An object of the present invention is to provide an illuminating device, an aviation obstacle light, and a system that can illuminate even if a light source or a power source is not provided nearby, and can further reduce costs.

  The present invention provides the following solutions.

  (1) An illuminating device that illuminates using light transmitted through a transmission path, which is connected to an upstream transmission path, to which the transmitted light is input, and input from the input terminal section A wavelength filter unit that transmits light having a wavelength other than a specific wavelength, an output terminal unit that outputs light that has passed through the wavelength filter unit to a downstream transmission path, and the wavelength filter unit 12 An illumination device comprising: a wavelength conversion unit that converts a wavelength of light having a specific wavelength; and a lamp unit that irradiates light converted by the wavelength conversion unit.

  According to the configuration of (1), the illuminating device according to the present invention is an illuminating device that illuminates using the light transmitted through the transmission line, and is transmitted from the input terminal connected to the upstream transmission line. The input light is input, light other than the specific wavelength among the input light is allowed to pass, and is output to the downstream transmission path. And the illuminating device which concerns on this invention converts the wavelength of the light of the specific wavelength which did not pass, and irradiates the converted light.

  Therefore, since the illuminating device according to the present invention uses the light transmitted through the transmission path, it can illuminate even if no light source or power source is provided nearby. Furthermore, since the illuminating device according to the present invention illuminates using light of a specific wavelength among the transmitted light and allows light other than the specific wavelength to pass through, when using many illuminating devices according to the present invention, The wavelength of light can be controlled and controlled collectively, and as a result, the cost when a large number of lighting devices are used can be reduced as compared with the prior art.

  (2) The lamp unit may further include a light reflecting layer portion that reflects the light converted by the wavelength converting portion, and a scattering portion that scatters the light reflected by the light reflecting layer portion. The lighting device described.

  According to the structure of (2), the illuminating device as described in (1) reflects the light converted by the wavelength conversion part, and scatters the reflected light. Therefore, the illuminating device according to the present invention reflects and scatters the light transmitted through the transmission path at the lamp unit, so that a wide range can be illuminated.

  (3) A photoelectric conversion unit that converts the input light into electric power, a power supply control unit that controls electric power converted by the photoelectric conversion unit, and a power supply from the power supply control unit, the lamp unit The illumination device according to (1) or (2), further comprising: a sensor unit that measures the illuminance of ambient light.

  According to the configuration of (3), the lighting device according to (1) or (2) converts the input light into electric power, controls the converted electric power, receives the power supply, and Measure the illuminance of the ambient light. Therefore, when a large number of illumination devices according to the present invention are used, the illuminance around the illumination device can be used to control the wavelength of the light in a collective manner, and as a result, when a large number of illumination devices are used. Cost can be reduced as compared with the prior art.

  (4) A light source device that outputs light, a light transmission device that multiplexes light output from the light source device as light of a plurality of different wavelengths, and transmits the multiplexed light, and light transmitted by the light transmission device An input terminal unit that is connected to an upstream transmission path and receives the transmitted light, and light other than a specific wavelength among the light input from the input terminal unit. A wavelength filter that passes through, an output terminal that outputs light that has passed through the wavelength filter to a downstream transmission line, and wavelength conversion that converts the wavelength of light of a specific wavelength that has not passed through the wavelength filter An illumination control system comprising: a lighting unit including a lamp unit that irradiates light converted by the wavelength conversion unit.

  According to the configuration of (4), in the illumination control system according to the present invention, the light source device outputs light, and the optical transmission device multiplexes and multiplexes the light output from the light source device as light of a plurality of different wavelengths. Transmitting light, the illumination device is input from the input terminal connected to the upstream transmission path the light transmitted by the light transmission device, let the light other than the specific wavelength pass through the input light, It outputs to the downstream transmission line, converts the wavelength of the light of the specific wavelength which did not pass among the input light, and irradiates the converted light. Therefore, the illumination device system according to the present invention uses a large number of illumination devices that illuminate using light having a specific wavelength among transmitted light and transmits light other than the specific wavelength, and controls the wavelength of the light. Monitoring and control can be performed in a lump, and as a result, the cost when a large number of lighting devices are used can be reduced as compared with the prior art.

  ADVANTAGE OF THE INVENTION According to this invention, even if it does not have a light source and a power supply nearby, it can illuminate and can provide the illuminating device, the aviation obstacle light, and the illuminating device system which can reduce cost more conventionally.

Furthermore, according to the present invention, when a large number of lighting devices are used, significant cost reduction and CO ₂ reduction can be realized. The facility for monitoring and controlling a large number of lighting devices at once can be made compact, and simplification and efficiency of monitoring and maintenance can be achieved.

It is a block diagram which shows the structure of the illuminating device 10 which concerns on one Embodiment of this invention. It is a figure which shows an example of a structure of the lamp | ramp part 101 of the illuminating device 10 which concerns on one Embodiment of this invention. It is a block diagram which shows the structure of the illuminating device system 20 which concerns on one Embodiment of this invention. It is a block diagram which shows the structure of the aviation obstacle light 30 which concerns on one Embodiment of this invention. It is a block diagram which shows the structure of the aviation obstacle light system 40 which concerns on one Embodiment of this invention. It is a figure which shows an example of the hardware constitutions of the monitoring control apparatus 400 of the aviation obstacle light system 40 which concerns on one Embodiment of this invention. It is a figure which shows an example of the monitoring control table of the aviation obstacle light system 40 which concerns on one Embodiment of this invention. It is a flowchart which shows the processing content of the aircraft obstacle light system 40 which concerns on one Embodiment of this invention. It is a figure showing an example of the whole figure of aviation obstacle light system 40 concerning one embodiment of the present invention.

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

[Example 1]
FIG. 1 is a block diagram showing a configuration of a lighting device 10 according to an embodiment of the present invention. The lighting device 10 is a device that illuminates using light transmitted through a transmission path. The illumination device 10 includes an input terminal unit 11, a wavelength filter unit 12, an output terminal unit 13, an optical connection unit 102 including a wavelength conversion unit 14, and a lamp unit 101.

  The input terminal unit 11 is connected to the upstream transmission path 201. The input terminal portion 11 receives light transmitted through the transmission path. The transmission path transmits light emitted from the light source and is configured by, for example, an optical fiber. As the light source, for example, there is a high-power laser using near infrared rays. The light emitted from the light source is multiplexed and transmitted to a plurality of light beams having different wavelengths by a wavelength division multiplexing (WDM) technique.

  The wavelength filter unit 12 allows light other than a specific wavelength to pass through the light input from the input terminal unit 11. For example, the wavelength filter unit 12 reflects light of a specific wavelength among the light of a plurality of wavelengths constituting the light transmitted by the optical fiber and allows light other than the specific wavelength to pass.

  The output terminal unit 13 outputs the light that has passed through the wavelength filter unit 12 to the downstream transmission path 202. That is, light other than a specific wavelength among the transmitted light is output from the output terminal unit 13 to the transmission path 202 and input to the input terminal unit 11 of the next lighting device 10.

  The wavelength conversion unit 14 converts the wavelength of light having a specific wavelength that has not passed through the wavelength filter unit 12. That is, the wavelength conversion unit 14 receives light having a specific wavelength reflected by the wavelength filter unit 12 and converts the wavelength of the incident light. For example, the wavelength conversion unit 14 converts the wavelength of light using a light emitting / fluorescent material that is excited by infrared light and up-converts to visible light emission (red).

  The lamp unit 101 includes a light reflecting layer unit 15 and a scattering unit 16. The light reflection layer unit 15 reflects the light converted by the wavelength conversion unit 14. Here, the light reflection layer portion 15 will be described with reference to FIG. FIG. 2 is a diagram illustrating an example of the configuration of the lamp unit 101 of the illumination device 10 according to an embodiment of the present invention. FIG. 2 (1) shows an optical fiber 150 through which light passes, and FIG. 2 (2) shows a cross-sectional view taken along line AA in FIG. 2 (1). As the optical fiber 150, for example, a side-emission optical fiber is used, and a core 151, a clad 152, and a light reflecting layer 153 disposed between the core 151 and the clad 152, as shown in FIG. Prepare. The light converted by the wavelength conversion unit 14 is reflected by the light reflection layer 153 of the optical fiber 150 of the lamp unit 101 and is emitted from the entire side surface of the optical fiber as shown in FIG.

  The scattering unit 16 scatters the light reflected by the light reflecting layer unit 15. For example, the scattering unit 16 scatters light using a light emitting / storing material on the glass surface of the lamp unit 101. For example, a high-intensity light-scattering polymer light guide is used as the light emitting / storing material. The high-intensity light-scattering polymer light guide can be composed of a high-intensity light-scattering light-guide polymer in which, for example, a micron-order heterogeneous structure is formed in a photonics polymer. Become.

  FIG. 3 is a block diagram showing a configuration of the illumination device system 20 according to an embodiment of the present invention. The illumination device system 20 includes a laser device 401 as a light source, an optical transmission device 402, and a plurality of illumination devices 10 having wavelength filter units 12 corresponding to different wavelengths. And the optical fiber cable which transmits the light output from the optical transmission apparatus 402 is connected to the input terminal part 11 of the one illuminating device 10, and the next illuminating apparatus 10 from the output terminal part 13 of the one illuminating device 10 is connected. The input terminal unit 11 is connected.

  The laser device 401 outputs high-power laser light as a light source.

The optical transmission device 402 multiplexes the light output from the laser device 401 as light of a plurality of different wavelengths by wavelength division multiplexing (WDM), and transmits the light through a single optical fiber cable. Light multiplexing is performed by multiplexing or not multiplexing light of a designated wavelength according to an instruction. An optical fiber cable is surrounded by a clad around a core, and the clad is covered with a coating to protect the fiber. The optical fiber cable can transmit light even when the optical fiber cable is bent, by reflecting the light with a difference in refractive index between the core and the clad and transmitting the light. For example, the optical transmission device 402 multiplexes light having wavelengths λ ₁ , λ ₂ ,..., Λ _X and transmits the multiplexed light using an optical fiber cable.

Among the plurality of lighting devices 10, one lighting device 10 transmits, for example, light having a wavelength other than λ ₁ out of light transmitted through an optical fiber cable and input from the input terminal unit 11, and λ ₂ ,. ... Λ _X wavelength light is output from the output terminal section 13. Then, the wavelength conversion unit 14 converts the light 414 having a wavelength of λ ₁ and irradiates the converted light. Furthermore, light 413 (light having a wavelength of λ ₂ ,..., Λ _X ) output from the output terminal unit 13 of one lighting device 10 is input to the next lighting device 10, and the next lighting device 10 , Among the input light, for example, light having a wavelength other than λ ₂ is allowed to pass, and light having a wavelength of λ ₃ ,..., Λ _X is output from the output terminal unit 13. Then, the light having the wavelength of λ ₂ is converted by the wavelength conversion unit 14 and the converted light is irradiated.

  Thus, even if the lighting device system 20 does not include a light source or a power source near the lighting device 10, the lighting device system 20 is turned on for each of the plurality of lighting devices 10 by transmitting light of a specific wavelength, and has a specific wavelength. By not transmitting light, each of the plurality of lighting devices 10 can be turned off.

[Example 2]
FIG. 4 is a block diagram showing the configuration of the aviation obstacle light 30 according to an embodiment of the present invention. The aviation obstacle light 30 further includes a photoelectric conversion unit 17, a power supply control unit 18, and a sensor 104 in addition to the configuration of the lighting device 10.

  The wavelength conversion unit 14 of the aviation obstacle light 30 converts near-infrared rays (1.3 to 1.6 μm) as a luminescent material through, for example, luminescent glass, thereby converting the wavelength and performing red conversion fluorescence by infrared light excitation. .

  The photoelectric conversion unit 17 converts the input light into electric power. That is, the photoelectric conversion unit 17 receives the power optical signal 411 (see FIG. 5) among the light transmitted through the transmission line and input from the input terminal unit 11, for example, by a photodiode (PD: Photodiode). And convert it to electric power.

  The power control unit 18 controls the power converted by the photoelectric conversion unit 17.

  The sensor 104 receives power supply from the power supply control unit 18 and measures the illuminance of light around the lamp unit 101. Illuminance data measured by the sensor 104 can be sent to, for example, the monitoring control device 400 by a communication optical signal 415 (see FIG. 5) using a part of the transmission path. The monitoring control device 400 can control the output of the light source based on the received illuminance data.

  The aviation obstacle light 30 has a light intensity of 10 cd when the place where it is installed is 60 m or more and 90 m or less and daytime obstacle signs are installed (Aviation Law Article 51-2, Aviation Law Enforcement Regulations Article 132-2) ). For this reason, when the light intensity by the structure of the illuminating device 10 is insufficient, an LED (Light Emitting Diode) 103 may be provided to supplement the light intensity. The LED 103 converts the transmitted light by the photoelectric conversion unit 17 and emits light by the electric power controlled by the power supply control unit 18. Note that the power source may be an independent power source that uses power and storage batteries by various power generation devices (for example, solar power generation, wind power generation, electrostatic induction method, vibration power generation, etc.).

  FIG. 5 is a block diagram showing a configuration of an aircraft obstacle light system 40 according to an embodiment of the present invention. The aviation obstacle light system 40 includes an aviation obstacle light 30, an optical transmission device 402, a laser device 401, and a monitoring control device 400.

The laser device 401 outputs laser light based on a control signal from the monitoring control device 400. The optical transmission device 402 transmits a plurality of lights having different wavelengths to the aviation obstacle light 30 through a transmission path. The optical transmission device 402 uses the wavelength division multiplexing technology (WDM) based on the control signal from the supervisory control device 400 to transmit the wavelength λ to the aviation obstacle lights 30 of the respective transmission towers # 1, # 2,. ₁ , λ ₂ ,..., Λ _X are allocated and transmitted. The aviation obstacle light 30 of the power transmission tower #n extracts only the light λ _{n having the} corresponding wavelength by the wavelength filter unit 12 and irradiates the extracted light 414 with the red light converted by the wavelength conversion unit 14. The photoelectric conversion unit 17 receives the optical signal 411 for power with a photodiode (PD: Photodiode) connected in series, and converts it into power. The power supply control unit 18 provides the electric power converted by the photoelectric conversion unit 17 to the sensor 104 by multistage control. The sensor 104 is operated by the power supply provided from the power supply control unit 18, measures the illuminance of the light around the lamp unit 101, and transmits it by the communication light signal 415.

  The transmission line uses OPGW (Optical Ground Wire). The OPGW incorporates an optical fiber in an overhead ground wire (an overhead power transmission line overhead on the power transmission line for the purpose of shielding lightning). For this reason, the aviation obstacle light system 40 using OPGW can construct a long-distance and wide-range system according to the high-quality and large-capacity transmission characteristics of the optical fiber.

  The monitoring control device 400 monitors and controls all the aviation obstacle lights 30 at once. For example, information related to the current state of the aviation obstacle light 30, for example, information on lighting or extinguishing of the aviation obstacle light 30, ambient illuminance received from the sensor 104, and the like are displayed on the aviation obstacle light system monitoring panel 403. Then, the supervisory control device 400 receives an instruction from the operator, and controls the light transmission device 402 to turn on or off for each aviation obstacle light 30 based on the received instruction or laser based on the ambient illuminance. An energy saving effect can be obtained by fine control such as adjusting the brightness of the aviation obstacle light 30 by controlling the output of the device 401.

  The aircraft obstacle light 30 may include a temperature sensor for monitoring heat generation, an abnormality detection sensor, a power consumption sensor, and the like in addition to the sensor 104 that measures illuminance. The monitoring control device 400 displays data from each sensor received by the communication light signal 415 on the aviation obstacle light system monitoring panel 403, and controls the optical transmission device 402 and the laser device 401 based on the data from each sensor. can do.

  FIG. 6 is a diagram illustrating an example of a hardware configuration of the monitoring control device 400 of the aviation obstacle light system 40 according to an embodiment of the present invention. The monitoring control device 400 includes a CPU (Central Processing Unit) 1000, a communication I / F 1040, a main memory 1050, a BIOS (Basic Input Output System) 1060, an I / O controller 1070, a hard disk 1074, a display device 1080, an input device 1100, and an input device 1100. An output I / F device 2000 is provided and connected by a bus line 1005.

  The CPU 1000 is a part that comprehensively controls the monitoring control device 400, and by appropriately reading and executing various programs stored in the hard disk 1074, the CPU 1000 cooperates with the hardware described above, and performs various functions according to the present invention. Realized.

  The communication I / F 1040 is a network adapter for enabling the monitoring control device 400 to be connected to another server or the like via a dedicated network or a public network.

  The main memory 1050 stores a program that is read and executed as appropriate, and stores various types of information created by the execution of the program.

  The BIOS 1060 stores a boot program executed by the CPU 1000 when the monitoring control device 400 is activated, a program depending on the hardware of the monitoring control device 400, and the like.

  Storage means such as a hard disk 1074 can be connected to the I / O controller 1070.

  The hard disk 1074 stores a program for the monitoring control apparatus 400 to execute the functions of the present invention, and stores a monitoring control table (see FIG. 7) and the like.

  The program provided to the monitoring control device 400 is provided by being stored in a recording medium such as the hard disk 1074 or a memory card. This program may be read from a recording medium via the I / O controller 1070 or downloaded via the communication I / F 1040 to be installed and executed in the monitoring control device 400.

  The display device 1080 displays a screen of a calculation processing result by the monitoring control device 400, a screen for receiving an operator instruction, and the like, and includes a display device such as a cathode ray tube display device or a liquid crystal display device.

  The input device 1100 is a device that performs input by an operator of the monitoring control device 400, and includes a keyboard and a mouse.

  The input / output I / F device 2000 connects the aviation obstacle light system monitoring panel 403, the laser device 401, the optical transmission device 402, and the sensor 104.

  The monitoring control device 400 stores the illuminance data received from each sensor 104 provided in the aviation obstacle light 30 in the monitoring control table (see FIG. 7), and the received illuminance data is stored in the aviation obstacle light system monitoring panel 403. indicate. Then, the monitoring control device 400 controls the output of the laser device 401 based on the received illuminance data, and controls the optical transmission device 402 to turn on / off each of the aviation obstacle lights 30 based on instructions from the operator.

  FIG. 7 is a diagram showing an example of the monitoring control table of the aviation obstacle light system 40 according to the embodiment of the present invention.

  The monitoring control table stores power transmission tower information, output light information, and ambient illuminance information. The power transmission tower information stores a steel tower ID and an aviation obstacle light ID for identifying the power transmission tower. The output light information stores a wavelength of light for turning on the aviation obstacle light 30 and output ON / OFF information. The ambient illuminance information stores illuminance data transmitted from the sensor 104 of the aviation obstacle light 30, and is stored separately for the illuminance before lighting and the illuminance after lighting.

  FIG. 8 is a flowchart showing the processing contents of the aircraft obstacle light system 40 according to the embodiment of the present invention. This process starts upon receiving a program start command and ends upon receiving a program end command.

  In step S101, the CPU 1000 determines whether or not the instruction from the operator is a turn on / off instruction. More specifically, the CPU 1000 determines whether data indicating whether the aviation obstacle light 30 is turned on or off is input from the input device 1100. If this determination is YES, the process moves to a step S102, and if NO, the process moves to a step S103.

  In step S102, the CPU 1000 stores the instruction from the operator in the monitoring control table, and controls the multiplexing of the wavelength of the light by the optical transmission device 402 in order to turn on / off the instructed aviation obstacle light 30. More specifically, the CPU 1000 controls the optical transmission device 402 so as to include and multiplex light having a wavelength corresponding to the instructed aviation obstacle light 30 when instructed to turn on by the operator. Similarly, when the operator instructs to turn off the light, the optical transmission device 402 is controlled so that the transmitted light does not include the light having the wavelength associated with the instructed aviation obstacle light 30. Thereafter, the CPU 1000 shifts the processing to step S101.

  In step S103, the CPU 1000 determines whether or not the instruction from the operator is an instruction to the laser. More specifically, the CPU 1000 determines whether data indicating an instruction to the laser is input from the input device 1100. If this determination is YES, the process moves to a step S104, and if NO, the process moves to a step S105.

  In step S104, the CPU 1000 controls the laser device 401 based on an instruction from the operator. More specifically, the CPU 1000 controls the laser apparatus 401 to output a signal so as to increase or decrease the output of the laser based on an instruction from the operator. Thereafter, the CPU 1000 shifts the processing to step S101.

  In step S105, the CPU 1000 determines whether sensor information has been received. If this determination is YES, the process moves to a step S106, and if NO, the process moves to a step S101.

  In step S106, the CPU 1000 stores the received sensor information in the monitoring control table. More specifically, based on the aviation obstacle light ID of the received sensor information, the CPU 1000 turns on when the output light information is OFF in the illuminance information area around the corresponding aviation obstacle light ID in the monitoring control table. In the front area, the illuminance data received is stored in the area after lighting when ON. Thereafter, the CPU 1000 shifts the processing to step S101.

  FIG. 9 is a diagram showing an example of an overall view of an aircraft obstacle light system 40 according to an embodiment of the present invention.

  In the aviation obstacle light system 40, the aviation obstacle light 30 is arranged on the power transmission tower 510, and the monitoring control device 400, the laser device 401, the optical transmission device 402, and the aviation obstacle light system monitoring panel 403 are provided in the control station 501, which is also a substation. The near-infrared rays (1.3 to 1.6 μm) are sent to the aviation obstacle light 30 through the optical fiber (OPGW). The aviation obstacle light system 40 can transmit near-infrared rays (1.3 to 1.6 μm) to an optical fiber (OPGW), and can transmit it to a long distance. The obstacle lights 30 can be collectively monitored and controlled.

  Furthermore, if necessary, an optical amplifier 511 may be installed in the communication station 503 via the OPGW to prevent the transmitted signal from being attenuated. In the case of a long distance from the laser device 401, the light level may be reduced due to loss loss, so the light level is amplified by the optical amplifier 511 (light amplification device) installed in the communication machine room of the communication station building 503 in the substation premises. By doing so, the aviation obstacle light 30 in a wide range (long distance) can be turned on.

  Furthermore, it is desirable to provide a similar laser device 401 and optical transmission device 402 as spares in the other substation 502 in consideration of the disconnection failure of the OPGW.

The aviation obstacle light 30 may be installed by separating the lamp unit 101 and the optical connection unit 102 (filter unit) into a lamp lamp 191 and an optical connection box 192, respectively. In the optical junction box 192 of the steel tower #n, only the specific wavelength λ _n is taken out by the wavelength filter unit 12, is excited to red light by the wavelength conversion unit 14, and is sent to the lamp lamp 191 to emit light. And except for specific wavelength (lambda) _n , it passes and is sent to the adjacent steel tower.

  According to the first embodiment, the illumination device 10 receives transmitted light from the input terminal unit 11 connected to the upstream transmission path, and allows light other than a specific wavelength to pass through the input light. Output from the output terminal section 13 to the downstream transmission path. And the illuminating device which concerns on this invention converts the wavelength of the light of the specific wavelength which did not pass, reflects the converted light, scatters, and irradiates light.

  The illumination device system 20 includes a laser device 401, an optical transmission device 402, and the illumination device 10. The laser device 401 outputs light, the optical transmission device 402 multiplexes the light output from the laser device 401 as light of a plurality of different wavelengths, and transmits the multiplexed light to the illumination device 10. The illumination device 10 The light is irradiated based on a specific wavelength among the input light. Therefore, since the illuminating device 10 uses the light transmitted by the transmission path, it can illuminate even if it does not have a light source or a power supply nearby. Furthermore, since the illuminating device 10 illuminates using light having a specific wavelength among the transmitted light and allows light other than the specific wavelength to pass, the illuminating device system 20 using a large number of the illuminating devices 10 has a wavelength of light. As a result, the cost when a large number of lighting devices 10 are used can be reduced as compared with the prior art.

  According to the second embodiment, the aviation obstacle light 30 further includes the photoelectric conversion unit 17, the power supply control unit 18, and the sensor 104 in addition to the configuration of the lighting device 10, and a specific part of the input light is specified. While irradiating red light based on the wavelength, the input light is converted into electric power, and the sensor measures the illuminance of ambient light using the converted electric power.

Further, the aviation obstacle light system 40 includes a monitoring control device 400, a laser device 401, an optical transmission device 402, and an aviation obstacle light 30. Then, the laser device 401 outputs near-infrared light under the control of the monitoring control device 400, and the light transmission device 402 multiplexes the light output from the laser device 401 as light of a plurality of different wavelengths under the control of the monitoring control device 400. The multiplexed light is transmitted to the aviation obstacle light 30, and the aviation obstacle light 30 emits red light based on a specific wavelength of the input light. Further, the aviation obstacle light 30 transmits the data measured by the sensor 104 to the monitoring control device 400, and the received monitoring control device 400 displays it on the aviation obstacle light system monitoring panel 403. Therefore, the aviation obstacle light system 40 according to the present invention can collectively monitor and control the wavelength of light when a large number of aviation obstacle lights 30 are used. The cost can be greatly reduced and the CO ₂ reduction can be realized. The aviation obstacle light system 40 according to the present invention can make the facility for monitoring and controlling a large number of aviation obstacle lights 30 in a compact manner, and can simplify and improve the efficiency of monitoring and maintenance.

  As mentioned above, although embodiment of this invention was described, this invention is not restricted to embodiment mentioned above. The effects described in the embodiments of the present invention are only the most preferable effects resulting from the present invention, and the effects of the present invention are limited to those described in the embodiments of the present invention. is not.

DESCRIPTION OF SYMBOLS 10 Illuminating device 11 Input terminal part 12 Wavelength filter part 13 Output terminal part 14 Wavelength conversion part 15 Light reflection layer part 16 Scattering part 17 Photoelectric conversion part 18 Power supply control part 20 Illumination device system 30 Aviation obstacle light 40 Aviation obstacle light system 101 Lamp Unit 102 Optical connection unit 104 Sensor 191 Lamp light 192 Optical connection box 201, 202 Transmission path 400 Monitoring control device 401 Laser device 402 Optical transmission device 403 Aviation obstacle light system monitoring panel 411 Optical signal 413, 414 Optical 415 Communication optical signal 501 Control Station 502 Substation 503 Communication station 511 Optical amplifier 1000 CPU
1005 Bus line 1040 Communication I / F
1050 Main memory 1060 BIOS
1070 I / O controller 1074 Hard disk 1080 Display device 1100 Input device 2000 Input / output I / F device

Claims (4)

An illumination device that illuminates using light transmitted through a transmission path,
An input terminal connected to the upstream transmission line and into which the transmitted light is input;
A wavelength filter unit that allows light other than a specific wavelength to pass through the light input from the input terminal unit; and
An output terminal unit that outputs light that has passed through the wavelength filter unit to a downstream transmission path;
A wavelength conversion unit that converts the wavelength of light of a specific wavelength that has not passed through the wavelength filter unit;
A lamp unit for irradiating the light converted by the wavelength conversion unit;
A lighting device comprising: The lamp section is
A light reflecting layer that reflects the light converted by the wavelength converter;
A scattering part for scattering the light reflected by the light reflection layer part;
The illumination device according to claim 1, further comprising: A photoelectric conversion unit that converts the input light into electric power;
A power supply control unit for controlling the power converted by the photoelectric conversion unit;
A sensor unit that receives power supply from the power supply control unit and measures the illuminance of light around the lamp unit;
The illumination device according to claim 1, further comprising: A light source device for outputting light;
An optical transmission device that multiplexes light output from the light source device as light of a plurality of different wavelengths, and transmits the multiplexed light;
An illumination device for illuminating the light transmitted by the light transmission device,
An input terminal connected to an upstream transmission line and receiving the transmitted light;
A wavelength filter unit that allows light other than a specific wavelength to pass through the light input from the input terminal unit; and
An output terminal unit that outputs light that has passed through the wavelength filter unit to a downstream transmission path;
A wavelength conversion unit that converts the wavelength of light of a specific wavelength that has not passed through the wavelength filter unit;
A lamp unit that irradiates the light converted by the wavelength conversion unit;
A lighting control system comprising:

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