JP2013161545A - Lighting fixture for street light - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable utilization of commercial power source with high probability of charging even upon earthquake, by enabling illumination by charging a storage battery with electric power from the commercial power source if the commercial power source is available upon the earthquake.SOLUTION: A control section 14 monitors power supply and its failure from a commercial power source at all times and controls a power source portion 3 so that a storage battery 9 is charged with electricity of solar power generation under conditions of power supply from the commercial power source, when a seismic intensity detected by a seismic sensor is below a predetermined level and the storage battery 9 is charged from the commercial power source, when a seismic intensity detected by the seismic sensor goes beyond a predetermined level during a predetermined period from a time point when a seismic intensity higher than the predetermined level is detected.

Description

  The present invention relates to a lighting device for a street lamp.

  Conventionally, street lamps have been proposed in which illumination is performed by electricity obtained by using solar power generation. For example, a battery-dedicated housing containing a battery that stores electricity generated by a solar panel is attached to the top of the column, and a solar panel is disposed on the housing, and an LED that receives power from the battery is used as a light source. There has been proposed a lamp body in which the lamp body containing the lamp body is arranged so as to project laterally from the housing.

  And in the illuminating device which has such a solar panel, as shown, for example in patent document 1, a storage battery is charged using not only photovoltaic power generation but a commercial power supply, and the electric power from the storage battery is obtained. A technique for illuminating with a different light source is shown. Also, there is a device that increases the illuminance of a light source that is lit by receiving power from a storage battery at night after an earthquake when an earthquake sensor is provided in a lighting device having a solar panel. 2.

JP 2009-124843 A International Publication Number WO2005 / 086542 Specification

  In this way, in a lighting device that has a solar panel to generate solar power and receive power supply from a commercial power source, solar power is generated by receiving solar radiation, and the generated power is charged to the storage battery, It is usual to receive lighting from the battery during twilight or at night, and when the amount of solar radiation during the day is small, it is usual to charge the battery with a commercial power source at night when the electricity bill is low Become operational. And in the event of an earthquake, in order to cope with the loss of commercial power, it will be charged for only a few days using solar power generation, and it will be shifted to an operation where only the power stored in the storage battery is used for lighting at twilight or at night It is provided to do.

  By the way, in general, an area where a power failure occurs immediately after an earthquake is relatively narrow. The infrastructure of electricity, gas, and water and sewage has been improved in terms of seismic resistance, and the seismic strength of living environment equipment such as buildings and houses has improved. Most of the areas that can be continued are widespread.

  For this reason, if the above-mentioned lighting device, which is capable of using solar power and commercial power, is installed in an area that has shaken but does not cause any damage, The following problems occur. The illuminating device described above, for several days, shifts to an operation mode corresponding to an earthquake in which the storage battery is charged using only photovoltaic power generation and an illumination is performed by discharging the storage battery immediately after the occurrence of the earthquake. Then, even if commercial power can be used, if the sufficient amount of solar radiation cannot be obtained due to bad weather, etc., the charge amount of the storage battery may be greatly reduced, and the above-described lighting device eliminates this problem. There is a problem that can not be.

  That is, this type of lighting device normally charges the storage battery with the power generated by solar power, and receives the power from the storage battery during twilight or at night, and when the amount of charge during the daytime is low. In addition, charging a storage battery using nighttime power is inexpensive in cost and should be operated with an emphasis on cost.

  On the other hand, after the earthquake, the certainty should be improved for lighting at twilight and at night, and although there is a risk of power failure in the commercial power supply, the storage battery can be charged as long as it receives power from the commercial power supply When charging a storage battery, it is desirable to avoid the use of photovoltaic power generation, which is difficult to ensure with certainty.

  Therefore, in view of the above circumstances, the present invention is a lighting device that performs photovoltaic power generation to charge a storage battery and also charges a storage battery from a commercial power source, as long as the commercial power source can be used during or after an earthquake. The purpose is to charge the storage battery with electric power from the commercial power source so that it can be illuminated, and to increase the reliability of charging even in situations where earthquakes are likely to occur frequently It is what.

(Invention of Claim 1)
The present invention has been made in view of the above problems, and covers the lamp body case with a canopy made of a solar panel covered with a transparent dome-shaped cover,
Inside the lamp body case, there is a light source unit comprising LEDs, a power source unit comprising a storage battery capable of charging electricity generated by the solar panel and charging from a commercial power source, and supplying power to the light source unit, and the light source And a lighting device for a street light in which a control unit for controlling the power supply unit is disposed,
It has a seismic intensity sensor,
The control unit constantly monitors power supply and loss from the commercial power source to the power source unit, and the seismic intensity detected by the seismic intensity sensor is less than a predetermined seismic intensity under the condition of the power supply from the commercial power source. Sometimes, the electricity of solar power generation through the solar panel is charged to a storage battery, and when the seismic intensity detected by the seismic intensity sensor is greater than or equal to a predetermined seismic intensity, the seismic intensity greater than or equal to this predetermined seismic intensity is detected for a predetermined period, A lighting device for a street lamp characterized by controlling a power supply unit so as to charge a storage battery from a commercial power supply to solve the above-mentioned problems.

(Invention of Claim 2)
And in this invention, the said power supply part is
The lighting of the light source unit in a predetermined period from the time when a seismic intensity equal to or greater than the predetermined seismic intensity is detected,
When the power supply unit receives power supply from a commercial power supply, it is performed by supplying power to the light source unit of the commercial power supply,
When the commercial power supply is lost, it can be performed by discharging the storage battery.

(Invention of Claim 3)
In the present invention, the power supply unit charges the storage battery with electricity of solar power generation through the solar panel until the power supply unit receives power supply from the commercial power supply under the condition of loss of commercial power supply. It can be said to be.

(Invention of Claim 4)
In the present invention, the power supply unit is
Under the condition that the seismic intensity sensor detects that the seismic intensity is not detected or the seismic intensity detected is less than a predetermined seismic intensity and the power supply unit is supplied with commercial power.
When the remaining charge of the storage battery is less than a predetermined amount, supply the power of the commercial power source directly to the light source unit,
When the remaining charge of the storage battery is equal to or greater than a predetermined amount, power can be supplied to the light source unit by discharging the storage battery.

(Effect of the invention of claim 1)
According to the present invention, under the condition that power is supplied from a commercial power source, when the seismic intensity detected by the seismic intensity sensor is equal to or greater than a predetermined seismic intensity, the power from the commercial power source is charged without using solar power generation. Therefore, it is possible to improve the certainty that lighting can be performed at twilight or at night compared to charging electric power obtained from solar power generation.

  In the embodiment described below, the predetermined seismic intensity indicates a vibration corresponding to a measured seismic intensity of 5 in a measurement seismometer managed by a public organization such as the Japan Meteorological Agency as will be described later. This seismic intensity of 5 is supposed to be able to confirm the shaking of the utility pole in outdoor conditions, but in today's areas where electricity, gas, and water and sewage infrastructure in general residential areas have improved in terms of earthquake resistance The possibility of loss of commercial power is low. On the other hand, an earthquake with a seismic intensity of 5 cannot be denied even if it is a precursor of an earthquake with a greater tremor, and the commercial power supply that supplies power to street lights etc. may be lost due to the greater tremor. is there. Therefore, it is useful to use a case where a seismic intensity sensor detects a large seismic intensity including a predetermined seismic intensity equivalent to seismic intensity 5 as an opportunity to charge a storage battery with a commercial power source.

(Effect of the invention of claim 2)
Specifically, the power supply unit operates under the control of the control unit, and the control unit turns on the light source unit for a predetermined period from when a seismic intensity equal to or greater than a predetermined seismic intensity is detected. When receiving power supply from a commercial power source, the power source unit is controlled so as to perform power supply to the light source unit of the commercial power source, and conversely, when the commercial power source is lost, the power source unit is controlled by discharging the storage battery. The part lights up. Thus, even when the commercial power supply is being supplied or lost, the lighting fixture can be turned on when necessary, and the reliability of the lighting fixture is improved.

(Effect of the invention of claim 3)
Specifically, the power supply unit operates under the control of the control unit, and the control unit operates under the condition of loss of commercial power supply until the power supply unit receives power supply from the commercial power supply. This power supply unit is controlled so as to charge the storage battery with electricity of solar power generation via the panel. Therefore, even if power from the commercial power source is lost, that is, in the event of a power failure, lighting can be performed under the discharge of the storage battery, and the reliability of the lighting fixture is improved.

  This corresponds to the case where a power failure occurs due to an earthquake, and if the general public is able to perform a normal or almost normal life at daytime, the commercial power supply is usually about one or two days after the power failure. It is now common for the battery to come back, and it is now common for the storage battery to have a charge amount to obtain the necessary lighting in about two days. Of course, depending on the extent of the earthquake, it is possible that the power outage will last for a long time, but in that case, the street lighting itself is useful to the extent that the street lighting and the outdoor environment are kept intact without any damage. It is difficult to think, and such a case is unexpected.

(Effect of the invention of claim 4)
Specifically, the power supply unit operates under the control of the control unit, and the control unit detects that the seismic intensity sensor does not detect an earthquake or the detected seismic intensity is less than a predetermined seismic intensity, and the power supply unit supplies power from a commercial power source If the remaining charge of the storage battery is less than a predetermined amount, the power of the commercial power supply is supplied directly to the light source unit without charging the storage battery, and conversely, the remaining charge of the storage battery When the amount is greater than or equal to a predetermined amount, the power source unit is controlled to supply power to the light source unit by discharging the storage battery, and the light source unit is turned on. Therefore, illumination can be performed when necessary without depending on the remaining charge of the storage battery, and the reliability of the lighting apparatus is improved.

It is explanatory drawing which shows an example which concerns on this invention. It is explanatory drawing which shows the state which opened the canopy in an example. It is explanatory drawing which shows an example in a cross section. It is explanatory drawing which shows roughly the control which performs normal operation | movement of a power supply part. It is explanatory drawing which shows schematically control of the power supply part under the use of the commercial power supply of the earthquake mode of daytime earthquake detection. It is explanatory drawing which shows schematically control of the power supply part under the commercial power loss in the earthquake mode of daytime earthquake detection. It is explanatory drawing which shows roughly control of the power supply part under the commercial power supply utilization of the earthquake mode of nighttime earthquake detection. It is explanatory drawing which shows roughly control of the power supply part under the loss of commercial power supply of the earthquake mode of nighttime earthquake detection.

Next, the present invention will be described in detail based on the embodiment shown in FIGS.
In FIG. 1, reference numeral 1 denotes a lighting device for a street light according to the present invention. The lighting device 1 is provided in a storage space 2a open to the upper surface of a substantially tray-shaped lamp main body case 2, which will be described later. The lamp body 5 is located on the upper surface side of the lamp body 5 and is pivotally attached to the rear side of the lamp body case 2 via a hinge so as to cover the upper surface of the lamp body 5 so that it can be opened and closed. The canopy 6 comprises a canopy 6, and on both sides of the canopy 6, there are provided locking tools 7 that can be locked to the lamp body 5 in order to keep the storage space 2 a closed by the canopy 6.

  An opening 8 is provided in the bottom surface of the lamp body case 2 in the lamp body 5, and the light source unit 4 is disposed so as to be positioned corresponding to the opening 8. The light source unit 4 is formed by arranging a plurality of LED light sources (LED chips) on a substrate, and light emitted from these LED light sources is irradiated toward the lower side of the lamp body 5 through the opening 8. For example, the configuration of the LED light source mounted on the substrate can be connected in 3 series and 8 parallel connections. In this case, normally, when one LED light source fails, at least three LED light sources are extinguished. However, if a diode is mounted for each LED light source, even if one LED light source fails, other LED light sources Can be turned off.

  On the lower surface side of the light source unit 4, that is, on the lower surface side of the substrate on which the LED chip is mounted, a reflecting member that condenses the diffused light and condenses the light forward so that the light does not spread backward. (Not shown) is provided.

  The power supply unit 3 is composed of a storage battery 9 that discharges and sends power to the light source unit 4. The power supply unit 3 is attached to the bottom surface side of the lamp body case 2 in the same manner as the light source unit 4. 3 and the light source unit 4 are electrically connected. Further, a column attachment 10 fixed to the lamp body case 2 from below is provided on the lower surface of the lamp body 5 on one end side. The column attachment 10 is fixedly attached to a column (not shown). By doing this, this lighting fixture 1 is fixed to the support | pillar.

  The canopy 6 is combined with the solar panel 11 for photovoltaic power generation using the upper one surface as a light receiving surface as shown in a cross section so as to cover the upper side of the solar panel 11 and integrated with the solar panel 11. It consists of Then, with the canopy 6 closed, the solar panel 11 is positioned so as to correspond to the upper surface of the lamp body 5 with the light receiving surface facing upward, and when solar power is generated, the generated electricity is sent to the power supply unit 3. The storage battery 9 of the power supply unit 3 is charged. The dome-shaped cover 12 is formed of a light-transmitting transparent plate and has an upwardly convex curved surface. The outer surface of the dome-shaped cover 12 includes an antifouling material containing a substance that exhibits high dirt removal properties by photocatalysis. The agent is applied.

  Thus, in this lighting fixture 1, since the solar panel 11 is utilized as one part of the canopy 6, the canopy 6 is opened without removing the solar panel 11 separately during maintenance of the power supply unit 3 and the light source unit 4. With the simple operation, the upper surface of the lamp body 5 is greatly opened, and visual confirmation with respect to the power supply unit 3 and the light source unit 4 is easy, and operations such as attachment and removal to the power supply unit 3 and the light source unit 4 are also easy. Become. Since the canopy 6 is configured to cover the storage space 2a of the lamp body case 2 in which the power supply unit 3 and the light source unit 4 are disposed so as to be openable and closable, the power supply unit 3 and the light source unit are disposed below the solar panel 11. 4 and, of course, other electric components (not shown) are also arranged in the storage space 2a as installation locations.

  In the lighting fixture 1, as described above, the solar panel 11, the power supply unit 3, the light source unit 4 and the control unit 14 described later are the main components, and are illuminated with electric power obtained from solar power generation. It constitutes a solar power illuminator that can irradiate light. And the solar power generation illuminator of one system which consists of this solar panel 11, the power supply part 3, the light source part 4, and the control part 14 is formed by arranging the dome-shaped cover on the upper part of the lamp body case. It becomes the structure arrange | positioned integrally in the inside of a lighting fixture housing.

  The power supply unit 3 is provided so as to be able to receive power supply from a commercial power supply, and the storage battery 9 can be charged by power supply from the commercial power supply. Thus, in this lighting fixture 1, the electric power obtained by solar power generation can be charged by being sent to the power supply unit 3, and the power supplied from the commercial power supply can also be charged by the power supply unit 3. Further, as will be described later, the power source unit 3 is controlled so as to send power supplied from a commercial power source directly to the light source unit 4 as necessary.

  The control unit 14 provided in the lamp body case 2 is connected to the power supply unit 3 and constantly acquires information on the operation status of the power supply unit from the power supply unit 3. The information on the power supply unit operation status is information generated from a sensor attached to the storage battery, and includes power generation amount, discharge amount, battery remaining amount data, environmental data, number of cycles, and error code. These are always acquired as power supply unit operation status information, and stored and managed as power supply unit information in association with date / time information from a timer (based on GPS time data) of the control unit 14 itself. .

  The operation of the control unit 14 is not limited to that described above. For example, the illuminance of light emitted from the light source unit can be reduced by adjusting the discharge current amount according to the remaining charge amount in the power supply unit 3.

  In this Embodiment, the storage battery of the said power supply part 3 uses the lithium ion battery, and comprises the power supply part combining several battery packs. The charge / discharge control for the power supply unit composed of the plurality of storage battery packs is one of the operations of the control unit.

  The control unit 14 is provided so as to receive, as a signal, the illuminance sensed by the illuminance sensor 15 disposed in a portion other than the solar cell module region on the upper surface of the solar panel 11 as shown in the figure. Based on the illuminance sensed by the illuminance sensor 15, the light source unit 4 is controlled to be turned on and off.

Normal operation An example of a normal operation by the control unit 14 related to charging and discharging in the lighting apparatus 1 will be described with reference to FIG. Note that this normal operation is an operation in a state where the seismic intensity sensor described later does not detect an earthquake (an earthquake up to a predetermined seismic intensity is not detected), or after a predetermined time has passed in this state (this embodiment will be described later in 72 This is an operation performed after a lapse of time.
(Step 1)
First, step 1 shows the daytime when the light source unit 4 is not turned on, and the storage battery 9 is controlled to be charged with the power generated by solar power at this time.
(Step 2)
And it transfers to step 2 which determines whether it is a twilight time or nighttime from conditions, such as the said illumination intensity sensor and time information. Note that “during twilight and nighttime” here is not an ambiguous time zone expression that makes us guess the darkness felt by people's appearance. The situation with a preset illuminance suitable for lighting a street light is expressed as “at dusk or at night”. Hereinafter, for ease of explanation, “night time” will be described, and other times will be described as “daytime”.

(Step 3)
If the control unit 14 determines in step 2 that the external environment is nighttime, as step 3, the control unit 14 further determines whether the remaining charge is 20% or more with respect to the capacity of the storage battery 9 of the power supply unit 3. Determine whether. If the control unit 14 determines that it is daytime in step 2, the control flow is returned to step 1.

  As will be apparent from the steps described later, the determination as to whether or not the remaining charge of the storage battery 9 in step 3 is 20% or more is a control for charging the storage battery with the power of solar power generation in step 1. Step 2 is performed only when it is determined that it is nighttime in Step 2 and it is determined in Step 2 that it is nighttime. That is, the operation of the control unit for confirming the remaining charge of the storage battery is only when a change from “daytime to nighttime” is confirmed. When “at night” and “the remaining charge of the storage battery is less than 20%”, power from the commercial power source is used for lighting until the next “daytime”, and the flow of control is shown in step 4-1. Will be described later.

(Step 4)
Based on the determination in step 3 (the remaining charge of the storage battery 9 is 20% or more), the process proceeds to step 4. As step 4, the control unit 14 starts discharging the storage battery 9.

(Step 5)
In response to power from the power supply unit 3 (discharge of the storage battery 9), the light source unit 4 is turned on as step 5.

(Step 6)
When the light source unit 4 is turned on, the control unit 14 proceeds to Step 6 in which it is determined whether the external environment is nighttime or daytime based on conditions such as an illuminance sensor. If the control unit 14 determines that it is nighttime in step 6, the control flow returns to step 4, while if it is determined that it is daytime, the discharge of the storage battery 9 is stopped and the light source unit 4 is turned off. , Control to return to step 1.

(Step 4-1)
The case where it is determined in step 3 that the remaining charge of the storage battery 9 is less than 20% will be described. Thus, if it is determined in step 3 that the remaining charge of the storage battery 9 is less than 20%, the flow of control shifts to step 4-1. In step 4-1, as shown in FIG. 4, the power supply unit 3 receives power supply from the commercial power supply, and does not pass power through the storage battery 9 (that is, without charging the storage battery with power). Is controlled to supply power to the light source unit 4 as it is.

(Step 5-1)
Then, the light source unit 4 is turned on as step 5-1 with the power from the power source unit 3 (under the power supply from the commercial power source).

(Step 6-1)
In the next step 6-1, the control unit 14 determines whether or not it is nighttime. If it is determined that it is nighttime, the control flow returns to step 4-1, and it is determined that it is daytime. The power supply of the commercial power source from the power supply unit 3 to the light source unit 4 is stopped, whereby the light source unit 4 is turned off, and thereafter, control is returned to step 1.

  Thus, in normal operation, the storage battery 9 is not charged by using a commercial power source. That is, in normal times, if the remaining charge of the storage battery 9 is 20% or more, the storage battery 9 is discharged, and if the remaining charge of the storage battery 9 is less than 20%, the storage battery 9 is not discharged, The power supply unit 3 is controlled so as to send power directly to the light source unit 4 without passing through the storage battery 9.

○ Operation at the time of earthquake The seismic intensity sensor is mounted in this lighting fixture 1, and based on the seismic intensity detected by the seismic intensity sensor at the time of the earthquake, the control unit 14 performs the next control in such a way as to interrupt the normal operation described above. Is provided. And the main point of control by the control part 14 at the time of this earthquake is to make it charge from the commercial power source regardless of day and night when electric power is obtained from the commercial power source. The power supply of the commercial power supply and its loss are constantly monitored, i.e., the power supply is supplied from the commercial power supply and charging to the power supply unit 3 is possible, or the power supply unit 3 is supplied with power from the commercial power after a power failure. It is constantly monitored whether or not charging is possible.

(Daytime)
(Step A01: Seismic mode operation for daytime seismic intensity detection)
First, the operation of the lighting apparatus during an earthquake will be described with reference to FIG. 5 showing an example in which the operation is interrupted during the daytime in a normal operation. Since it is daytime, it is interrupted to the stage where electric power is charged to the storage battery by solar power generation. When the seismic intensity sensor detects a seismic intensity of seismic intensity 5 or more, it becomes the next step A01 in the operation at the time of the earthquake. The control unit 14 operates. In this step A01, when the seismic intensity sensor detects a seismic intensity of 5 or more, the time measurement of 72 hours is started by a time measuring means such as a timer from the time when the predetermined seismic intensity (seismic intensity 5) is detected. The seismic intensity 5 of the seismic intensity detected by the seismic intensity sensor, which is a condition for shifting to step A01, refers to a tremor corresponding to the seismic intensity 5 measured by a seismometer managed by a public organization such as the Japan Meteorological Agency. This seismic intensity sensor does not derive the value of the seismic intensity measured by the measuring seismometer.

(Step A02)
In the next step A02, the control unit 14 determines whether or not the power of the commercial power source is supplied. In addition, when the control part 14 determines with a power failure, the flow of control transfers to the step without the commercial power supply mentioned later.

(Commercial power supply available)
(Step A03)
When the control unit 14 determines in step A02 that power is supplied from a commercial power source, the control unit 14 stops charging the solar battery from solar power generation as step A03.

(Step A04)
Next, in step A04, control is performed so that the storage battery 9 is charged from the commercial power source. The operation of charging the storage battery 9 with the electric power from the commercial power source is not limited to day and night.

(Step A05)
If the storage battery 9 is charged with electric power from the commercial power source in step A04, the controller 14 next determines whether or not it is nighttime in step A05. If it is determined that it is daytime, the flow of control returns to step A04.

(Step A06)
When it is determined at night in step A05, the control unit 14 performs direct power supply to the light source unit 4 of the commercial power source as step A06 while charging the storage battery 9 by power supply of the commercial power source in the previous step. The light source unit 4 is controlled to be turned on. In this case, the storage battery 9 itself is charged but not discharged. That is, the power supply unit 3 charges the storage battery 9 and closes a circuit that does not pass through the storage battery, and supplies the power of the commercial power source to the light source unit 4.

(Step A07)
In step A07 after the light source unit 4 is turned on, the control unit 14 determines whether or not 72 hours have elapsed since the predetermined seismic intensity was detected by the seismic intensity sensor. In addition, when it determines with 72 hours having passed in this step A07, the control part 14 is controlled to return this lighting fixture 1 to normal operation | movement.

(Step A08)
In the determination of whether or not 72 hours have elapsed in step A07, if the control unit 14 determines that 72 hours have not elapsed, in the next step A08, the control unit 14 receives power from the commercial power source. It is determined whether it is supplied. That is, it is a step for determining whether or not a power failure has occurred as in step A02. When the control unit 14 determines that a power failure has occurred, the control flow shifts to a step without commercial power supply, which will be described later.

(Step A09)
When the control unit 14 determines in step A08 whether or not the power of the commercial power supply is being supplied, it is nighttime as the determination operation in the next step A09. It is determined whether or not. Here, when it is determined that it is nighttime, the flow of control returns to step A06.

(Step A10)
When it is determined in Step A09 that it is daytime instead of nighttime, the control unit 14 stops the power supply to the light source unit 4 of the commercial power source and turns off the light source unit 4 as shown in Step A10. Control. In addition, the charge by the electric power supply from the commercial power source with respect to the storage battery 9 is continuing.

(Step A11)
After the light source unit 4 is turned off in step A10, in step A11, the control unit 14 determines whether or not 72 hours have elapsed since the predetermined seismic intensity was detected. If it is determined in step A11 that 72 hours have elapsed, the control unit 14 controls the lighting apparatus 1 to return to normal operation. On the other hand, if it is determined that 72 hours have not elapsed, the process proceeds to the next step A12.

(Step A12)
In step A12, the control unit 14 determines whether or not the power of the commercial power source is supplied. That is, it is a step of determining whether or not a power failure has occurred, similar to steps A02 and A08. Here, when the control unit 14 determines that the commercial power supply can be supplied, the control proceeds to step A05 where it is determined whether it is nighttime from the relationship that the light source unit 4 is turned off in step A10. It is provided so that the flow returns. When the control unit 14 determines that the commercial power cannot be supplied (power failure), the control flow shifts to a step without commercial power supply, which will be described later.

(No commercial power supply)
FIG. 6 shows a control flow when the control unit 14 determines that the commercial power source is lost in the above-described steps A02, A08, and A12. Steps A01 to A12 described above show the flow of control that starts by detecting an earthquake (seismic intensity of 5 or more) during the daytime, and are based on charging using the power of the supplied commercial power supply. There is a step A03 for stopping the charging of the storage battery by solar power generation in the course of the steps. Therefore, in any of the cases where it is determined that the commercial power source has been lost in Steps A02, A08, and A12, as a next step, be sure to go through a step of “charging the storage battery with photovoltaic power”. Yes. Therefore, according to the loss of commercial power in the determination in step A08 performed at night, the control flow “charges the power of the photovoltaic power generation to the storage battery” at night, but in subsequent step A061 (described later) There is no problem because charging to the storage battery by solar power generation is stopped.

(Step A051)
As shown in FIG. 6, after the control process for charging the power of the photovoltaic power generation to the storage battery is performed, it is determined whether or not it is nighttime as shown in step A051 as the next step. If it is determined that it is not nighttime, the process returns to the control process of charging the storage battery with the power of the above-described photovoltaic power generation. If it is determined that it is nighttime, the process proceeds to the next step A061.

(Step A061)
If it is determined in the previous step A051 that it is nighttime, the control unit 14 stops charging the storage battery 9 by solar power generation, and controls the light source unit 4 to be lit by discharging the storage battery 9.

(Step A071)
In step A071, after the light source unit 4 is turned on in step A061, the control unit 14 determines whether or not 72 hours have elapsed since the predetermined seismic intensity was detected. In addition, when it determines with 72 hours having passed in this step A071, the control part 14 is controlled to return this lighting fixture 1 to normal operation | movement.

(Step A081)
In the determination of whether or not 72 hours have elapsed in step A071, if the control unit 14 determines that 72 hours have not elapsed, in next step A08, the control unit 14 supplies the power of the commercial power supply. It is determined whether or not it has been done. That is, in this step A081, it is a step which determines whether the commercial power source which was in the power failure state has recovered, and when the control unit 14 determines that there is a power failure, the control flow shifts to the next step A091. . On the other hand, when it is determined that the commercial power source has recovered, the control flow is shifted to Step A03.

(Step A091)
If the control unit 14 determines in step A081 that commercial power is not supplied, it determines whether or not it is nighttime in next step A091. Here, when it is determined that it is nighttime, the flow of control returns to step A061, and the discharge of the storage battery 9 is continued.

(Step A101)
When it is determined in step A091 that it is daytime instead of nighttime, as shown in step A101, the control unit 14 controls to stop discharging the storage battery 9 and turn off the light source unit 4.

(Step A111)
After the light source unit 4 is turned off in step A101, in step A111, the control unit 14 determines whether or not 72 hours have elapsed since the predetermined seismic intensity was detected. If it is determined in step A111 that 72 hours have elapsed, the control unit 14 controls the lighting apparatus 1 to return to normal operation. On the other hand, if it is determined that 72 hours have not elapsed, the flow of control proceeds to the next step A121.

(Step A121)
This step A121 is the same control as the above step A081, and the control unit 14 determines whether or not the power of the commercial power source is supplied. If the control unit 14 determines that there is a power outage at the stage of step A121, the control flow returns to the point where the storage battery is charged again with the power of the photovoltaic power generation. When it is determined that the commercial power supply has been recovered, the control flow is shifted to Step A03.

(At night)
(Step B01: Seismic mode operation for seismic intensity detection at night)
Next, a description will be given based on FIG. 7 showing an example in which an operation at the time of an earthquake is interrupted at night in a normal operation. Since the normal operation is performed at night, the storage battery 9 is discharged and the light source unit 4 is interrupted. When the seismic intensity sensor detects a seismic intensity of 5 or greater, In addition, the controller 14 operates as follows for nighttime use. In FIG. 7, the first operation is represented as step B01. In this step B01 as well, when a seismic intensity sensor detects a seismic intensity of 5 or more, the predetermined seismic intensity (seismic intensity 5) is detected as in the case of detecting an earthquake during the daytime. From this point, time measurement for 72 hours is started by time measurement means such as a timer.

(Step B02)
In the next step B02, the control unit 14 determines whether or not the power of the commercial power source is supplied. Here, when it is determined that the power is not supplied, the flow of control is provided to shift to step B031 described later.

(Commercial power supply available)
(Step B03)
When the control unit 14 determines in step B02 that power is supplied from the commercial power source, in step B03, the control unit 14 starts power supply from the commercial power source to the storage battery 9 of the power source unit 3. Control is performed so that the storage battery 9 is charged. The operation of charging the storage battery 9 with the electric power from the commercial power source is not limited to day and night.

(Step B04)
Next, the control unit 14 controls the light source unit 4 to be lit by supplying power to the light source unit 4 directly to the light source unit 4 as step B04. In this case, the power supply unit 3 charges the storage battery 9, and a circuit not passing through the storage battery is closed to supply commercial power to the light source unit 4. (Refer to step A06)

(Step B05)
After turning on the light source unit 4 by directly using the power of the commercial power source, the control unit 14 determines whether or not 72 hours have elapsed since the predetermined seismic intensity was detected as step B05. In addition, when it determines with 72 hours having passed in this step B05, it controls to return this lighting fixture 1 to normal operation | movement.

(Step B06)
In the determination of whether or not 72 hours have elapsed in step B05, if the control unit 14 determines that 72 hours have not elapsed, in the next step B06, the control unit 14 supplies the commercial power. It is determined whether or not it has been done. When the control unit 14 determines that there is a power failure, the flow of control shifts to a step without commercial power supply described later.

(Step B07)
In the determination of whether or not the commercial power supply is supplied in step B06, if the control unit 14 determines that the commercial power supply is possible, is the night time as the determination operation in step B07? Determine whether or not. Here, when it is determined that it is nighttime, the flow of control returns to step B04.

(Step B08)
When it is determined in Step B07 that it is daytime instead of nighttime, the control unit 14 stops the power supply to the light source unit 4 of the commercial power source and turns off the light source unit 4 as shown in Step B08. Control. Note that the storage battery 9 is charged by supplying power from a commercial power source.

(Step B09)
After the light source unit 4 is turned off in step B08, in step B09, the control unit 14 determines whether or not 72 hours have elapsed since the predetermined seismic intensity was detected. If it is determined in step B09 that 72 hours have elapsed, the control unit 14 controls the lighting device 1 to return to normal operation. On the other hand, if it is determined that 72 hours have not elapsed, the process proceeds to the next step.

(Step B10)
In the determination of whether or not 72 hours have elapsed in step B09, if the control unit 14 determines that 72 hours have not elapsed, in step B10, the control unit 14 is supplied with power from the commercial power source. It is determined whether or not. When the control unit 14 determines that there is a power failure, the flow of control shifts to a step without commercial power supply described later.

(Step B11)
In the determination of whether or not the commercial power is supplied in step B10, if the control unit 14 determines that the commercial power can be supplied, is the night time as the determination operation in step B11? Determine whether or not. Here, when it is determined that it is nighttime, the flow of control returns to step B04. Further, when it is determined that it is daytime, the flow of control is provided so as to return to step B08. As a result, the light source unit 4 remains unlit while the commercial power supply is stopped.

(No commercial power supply)
(Step B031)
As described above, the control flow when the control unit 14 determines in step B02, B06, B10 that the commercial power source is lost is shown in FIG. Steps B01 to B11 described above show a flow of control that starts by detecting an earthquake (seismic intensity of 5 or more) at night, and is based on charging the storage battery using the power of the supplied commercial power supply. However, after this step B031, the commercial power supply itself has been lost, and in the previous stage of step B02, the storage battery 9 is discharged during normal nighttime and the light source unit 4 is lit. From the beginning of the control flow when an earthquake is detected at night and it is determined that the commercial power supply cannot be supplied, “discharge of the storage battery 9” for turning on the light source unit 4 and at night “Stopping the charging of the storage battery by solar power generation of the light source unit 4” is provided in step B031.

  In Step B10, an earthquake is detected at night and it is determined that the commercial power supply cannot be supplied as the commercial power supply is lost during the daytime. In this case, from the state where the light source unit is turned off during the daytime. Although the control flow goes through the stage of “lighting the light source” in step B031, there is a later-described step B061 for determining “whether it is nighttime or daytime”. The state to do is avoided.

(Step B041)
Next, in step B041, the control unit 14 determines whether or not 72 hours have elapsed since the predetermined seismic intensity was detected. If it is determined in step B041 that 72 hours have elapsed, the control unit 14 controls the lighting apparatus 1 to return to normal operation.

(Step B051)
In the determination of whether or not 72 hours have elapsed in step B041, if the control unit 14 determines that 72 hours have not elapsed, in step B051, the control unit 14 is supplied with power from the commercial power source. It is determined whether or not. When it is determined that commercial power can be supplied, the flow of control shifts to step B03 after the commercial power supply shown in FIG. When it is determined that the commercial power is not supplied, the process proceeds to the next step.

(Step B061)
If it is determined in step B051 that commercial power is not supplied, it is determined in step B061 whether it is nighttime. Here, when it is determined that it is nighttime, the flow of control returns to Step B031. If it is determined that it is daytime, the process proceeds to step B061.

(Step B071)
When it is determined in Step B061 that it is daytime instead of nighttime, the control unit 14 controls the light source unit 4 to be extinguished by stopping discharging in the storage battery 9 as shown in Step B071.

(Step B081)
After the light source unit 4 is turned off in the step B071, the control unit 14 determines whether or not 72 hours have elapsed since the predetermined seismic intensity was detected in step B081. If it is determined in step B081 that 72 hours have elapsed, the control unit 14 controls the lighting apparatus 1 to return to normal operation. On the other hand, if it is determined that 72 hours have not elapsed, the process proceeds to the next step.

(Step B091)
As described above, when it is determined in step B081 that 72 hours have not elapsed, in step B091, the control unit 14 determines whether or not the power of the commercial power source is supplied. If it is determined that commercial power can be supplied, the flow of control proceeds to step B03 in the case where commercial power is supplied. When it is determined that the commercial power is not supplied, the process proceeds to the next step.

(Step B101)
Based on the relationship that the light source unit 4 is turned off in step B071, it is determined in this step B101 whether or not the control unit 14 is nighttime. If it is determined that it is nighttime, control is performed in step B031. It is provided so that the flow of If the control unit 14 determines that it is not nighttime, the process proceeds to the next step.

(Step B111)
Since it is determined in the previous step B101 that it is daytime, the control unit 14 performs control for charging the storage battery 9 with the electric power generated by photovoltaic power generation as this step B111, and the control flow returns to step B081. Is provided.

  As described above, in the event of an earthquake, if the seismic intensity detected by the seismic intensity sensor is less than seismic intensity 5, if the power supply from the commercial power supply is performed from the result of monitoring the power supply of the commercial power supply and its loss, At the daytime, the battery 9 is charged with power from the solar power generation, and the storage battery 9 is discharged at night to send power to the light source unit 4 so that it is turned on and illuminated, and receives power from a commercial power source as necessary. The power supply unit 3 is controlled so as to charge the storage battery 9. That is, although the earthquake is detected, the lighting device 1 is provided so as to maintain a normal operation.

  Also, in the event of an earthquake, if the seismic intensity detected by the seismic intensity sensor is greater than or equal to seismic intensity 5, from the result of monitoring the commercial power supply and its loss for a predetermined period from the time when this seismic intensity 5 was detected, If the conditions under which the power supply is performed are satisfied, the storage battery 9 is charged with power from the commercial power source regardless of day or night, and the power of the commercial power source is directly sent to the light source unit 4 at night to be lit. The power supply unit 3 is controlled to perform illumination.

  In addition, in order to compensate for the decrease in the amount of charge of the storage battery 9, the period for continuing the operation of charging the storage battery 9 with power from the commercial power source regardless of day or night is 72 hours, but is not limited. Further, when a seismic intensity of seismic intensity 5 or higher is detected again while the operation corresponding to the earthquake is continued, control is performed so as to continue for a predetermined period from the newly detected seismic intensity. Then, after the predetermined period has elapsed, the control unit 14 controls the power supply unit 3 so as to shift to a normal operation.

  On the other hand, if the control unit 14 detects a power failure state from the result of monitoring the power supply and loss of the commercial power supply in the event of an earthquake, the power supply of the commercial power supply is restored regardless of the seismic intensity detected by the seismic intensity sensor. During this time, the power supply unit 3 is controlled so as to charge the storage battery 9 with the power generated by the solar power generation. As a result, even during nighttime in a power failure state, the light source unit 4 is turned on and illuminated by receiving a discharge from the power source unit 3 charged by solar power generation.

  And, when the lost state of the commercial power source is resolved and power supply is detected, if the power supply is detected is within a predetermined period after the seismic intensity sensor detects seismic intensity 5 or more, the above-mentioned As described above, the storage battery 9 is charged by supplying power from a commercial power source regardless of day and night, and the power source unit 9 is controlled so that illumination is performed by the power of the commercial power source at night. When the power supply is detected, when the seismic intensity sensor detects a seismic intensity of 5 or more and a predetermined period has elapsed, control is performed so that normal operation is performed.

  Further, in the control related to the earthquake response operation, the control unit 14 constantly monitors the voltage of the commercial power source even during the daytime when the commercial power source can be used. In the case of a power failure that loses power, control is performed to immediately shift to the step in the case where the power supply of the commercial power source is impossible.

DESCRIPTION OF SYMBOLS 1 ... Street lighting fixture 2 ... Lamp main body case 3 ... Power supply part 4 ... Light source part 5 ... Lamp main body 6 ... Canopy 8 ... Opening 9 ... Storage battery 11 ... Solar panel 12 ... Domed cover 13 ... Transmission / reception part 14 ... Control part

Claims (4)

The lamp case is covered with a canopy made of a solar panel with a transparent dome-shaped cover,
Inside the lamp body case, there is a light source unit comprising LEDs, a power source unit comprising a storage battery capable of charging electricity generated by the solar panel and charging from a commercial power source, and supplying power to the light source unit, and the light source And a lighting device for a street light in which a control unit for controlling the power supply unit is disposed,
It has a seismic intensity sensor,
The control unit constantly monitors power supply and loss from the commercial power source to the power source unit, and the seismic intensity detected by the seismic intensity sensor is detected or not detected under the condition of the power supply from the commercial power source. When the seismic intensity is below a predetermined seismic intensity, the electricity of the solar power generation via the solar panel is charged to the storage battery, and when the seismic intensity detected by the seismic intensity sensor is greater than the predetermined seismic intensity, the seismic intensity exceeding the predetermined seismic intensity is detected. A street lamp luminaire characterized by controlling a power supply unit so as to charge a storage battery from a commercial power source during a period. The power supply section
The lighting of the light source unit in a predetermined period from the time when a seismic intensity equal to or greater than the predetermined seismic intensity is detected,
When the power supply unit receives power supply from a commercial power supply, it is performed by supplying power to the light source unit of the commercial power supply,
The street lamp lighting device according to claim 1, wherein when the commercial power source is lost, the storage battery is discharged.   The power source unit charges the storage battery with electricity of solar power generation through the solar panel until the power source unit receives power supply of the commercial power source under the condition of loss of commercial power source. A lighting device for a street light according to 1 or 2. The power supply section
Under the condition that the seismic intensity sensor detects that the seismic intensity is not detected or the seismic intensity detected is less than a predetermined seismic intensity and the power supply unit is supplied with commercial power.
When the remaining charge of the storage battery is less than a predetermined amount, supply the power of the commercial power source directly to the light source unit,
The street lamp lighting device according to claim 1, wherein when the remaining charge of the storage battery is equal to or greater than a predetermined amount, electric power is supplied to the light source unit by discharging the storage battery.

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