JP5953663B2 - Traffic signal controller - Google Patents

Description

  The present invention relates to a traffic signal controller that controls lighting or extinguishing of a signal lamp.

  At an intersection or pedestrian crossing, a traffic signal controller is installed to control the lighting or extinguishing of the blue, yellow, red, and blue arrows of the signal lamp at predetermined time intervals.

In addition, as a traffic signal controller of this type, in order to increase the reliability of traffic signal control by securing a power source even when the commercial power source is interrupted due to a disaster or the like, a commercial power source of AC 100V is used as the power source of equipment including a signal lamp. One that can be switched between a normal operation to be used and a battery operation that uses a DC voltage of the battery is known (see Patent Document 1).
By providing the battery, the operation of the traffic signal controller can be maintained by operating the battery even when the commercial power supply is shut off.

  Moreover, in the traffic signal apparatus of patent document 1, the solar cell is connected and a battery can be charged with the electric power generated with the solar cell.

JP 2008-71176 A

Even if the battery is configured to be charged with the power generated by the solar cell, if the battery is fully charged, the power cannot be stored even if the solar cell generates power. For this reason, the generated power is not used, but a commercial power source is used, resulting in waste.

  Therefore, an object of the present invention is to reduce waste when storing power generated by a power generation device that generates power using natural energy such as a solar battery, and to suppress the use of a commercial power source.

(1) The present invention is a traffic signal controller that controls the timing of switching the color of a signal lamp, and a battery that can be charged from a power generator that generates power using commercial power and natural energy, and the amount of power generated by the power generator is predetermined. A control unit that performs partial discharge for discharging a part of the charge amount of the battery by driving the signal lamp with the battery when the power generation reference amount is exceeded. It is a traffic signal controller.

  According to the present invention, even if the charge amount of the battery is large, the charge amount is reduced by performing partial discharge for discharging a part of the charge amount of the battery, and further charging is possible. Therefore, the opportunity to store the power generated by the power generation device that generates power using natural energy increases, and the use of the commercial power source can be suppressed, so that waste is reduced.

(2) The control unit executes the partial discharge when the power generation amount by the power generator exceeds a predetermined power generation reference amount and the charge amount of the battery reaches a predetermined charge reference amount. Is preferred. In this case, partial discharge is performed when the amount of charge of the battery is large enough to reach a predetermined charge reference amount. If partial discharge is performed when the amount of charge of the battery is small, it takes a very long time to recharge, and there is a possibility that a sufficient amount of charge cannot be ensured when a situation where battery driving is required occurs. On the other hand, if the amount of charge of the battery is large enough to reach a predetermined charge reference amount, if partial discharge is performed, it is easy to charge even if partial discharge is performed, and battery drive is required. Even when a situation occurs, it is easy to secure a sufficient amount of charge.

(3) It is preferable that the control unit adjusts the discharge amount based on information on a power generation amount by the power generation device or a factor affecting the power generation amount by the power generation device. In this case, the discharge amount can be adjusted appropriately.

(4) It is preferable that the information regarding the factor affecting the amount of power generated by the power generation device is information regarding solar radiation. Since the power generation amount of solar power generation depends on the state of solar radiation, the discharge amount can also be adjusted so as not to cause overdischarge when adjusted based on information on solar radiation.

(5) It is preferable that the said control part drives the said signal lamp device with the said commercial power supply after completion of the said partial discharge.

  In this case, after the partial discharge is completed, the signal lamp device is driven by a commercial power source, whereby the battery can be efficiently recharged by the power generation device.

(6) It is preferable that the charge reference amount is a charge amount when the battery is almost fully charged. In this case, since partial discharge is performed when the battery is almost fully charged, the remaining capacity of the battery is unlikely to decrease, and there is little damage to the battery function of backup at power failure.

  According to the present invention, even if the amount of charge of the battery is large, by performing partial discharge that discharges part of the amount of charge of the battery, the amount of charge is reduced, and further charging is possible. Therefore, the opportunity to store the power generated by the power generation device that generates power using natural energy increases, and the use of the commercial power source can be suppressed, so that waste is reduced.

It is a block diagram which shows the structural example of the traffic signal controller which concerns on this invention. It is a flowchart of the 1st process of the power supply control of a traffic signal controller. It is a flowchart of the 2nd process (partial discharge process) of the power supply control of a traffic signal controller. It is a flowchart of the partial discharge process which concerns on a modification.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[Configuration of traffic signal controller]
FIG. 1 is a block diagram showing a configuration example of a traffic signal controller 1 according to the present invention.
The traffic signal controller 1 according to the present embodiment includes a communication unit 2, a control unit 3, a power supply unit 4, a battery 10, a lamp driving unit 11, and an interface unit 12. In FIG. 1, only one lamp driving unit 11 that drives the signal lamp 51 is illustrated, but a plurality of actual lamp driving units 11 are provided according to the number of signal lamps 51.
The traffic signal controller 1 also includes an interface unit 12 for exchanging signals with an external device. The interface unit 12 is connected with an ultrasonic vehicle sensor 52, an optical beacon 53, an image processing vehicle sensor 54, a traffic information board 55, a push button device 56, another traffic signal controller 101, and the like. Can exchange data with other devices.

A central device 6 (also referred to as a traffic control device) installed in the traffic control center is connected to the communication unit 2 of the traffic signal controller 1 through a predetermined communication line. The central device 6 may be installed in a building other than the traffic control center.
The central device 6 is connected to a plurality of centralized traffic signal controllers 1 in the jurisdiction area of its own device through a communication line. From the central device 6 and each centralized traffic signal controller 1, traffic signals are transmitted. A control system is configured.
In addition, the traffic signal controller 1 may be a spot type that controls the signal lamp alone without performing communication with the central device 6.

  The control unit 3 of the traffic signal controller 1 is for controlling the signal lamp 51 and the like, and performs processing for determining the switching timing of turning on or off of the signal lamp 51.

  The power source 4 of the traffic signal controller 1 is connected to a commercial power source 7 (for example, AC 100V AC power source) as an external power source and a battery 10 as an internal power source. Further, the power supply unit 4 is connected to power generators 8 and 9 using natural energy (renewable energy) such as a solar cell (solar panel) 8 and / or a wind power generator 9. The power generation devices 8 and 9 are connected to the power supply unit 4 via the power generation meter 20. Note that a power generation device such as a solar battery (solar panel) 8 and / or a wind power generation device 9 is installed in the vicinity of the signal lamp 15.

  The power supply unit 4 includes a first switching unit 41 that switches a power supply source for charging the battery 10, and a second switching unit 42 that switches a power source for driving the signal lamp device 51 and the traffic signal controller 1. Yes.

The first switching unit 41 includes a switch circuit, and uses the first charging mode (normal mode) in which the commercial power supply 7 is used as a power supply source for charging, and the power generation devices 8 and 9 as power supply sources for charging. The second charging mode can be switched.
The second switching unit 42 includes a switch circuit, and includes a first driving mode (normal mode) in which a commercial power source is used as a power source for driving the signal lamp 51 and the battery 10 as a power source for driving the signal lamp 51 and the like. The second drive mode using can be switched.

The power supply unit 4 includes a power supply control unit 43 for controlling the first switching unit 41 and the second switching unit 42.
The power supply control unit 43 can switch the mode of each of the switching units 41 and 42 by outputting a switching control signal to the first switching unit 41 and the second switching unit 42.

  The traffic signal controller 1 is in the first drive mode and the first charge mode, which are normal modes, at normal times. That is, in normal times, the signal lamp 51 and the like are operated by the commercial power source 7, and the battery 10 is charged by the commercial power source 7. Note that AC power from the commercial power source 7 is converted into DC power by the converter 45 and is supplied to the battery 10 via the first switching unit 41.

The power supply control unit 43 performs control to switch to the second charge mode and / or the second drive mode as necessary, operates the signal lamp 51 and the like with the battery 10, and sets the battery 10 with the power generation devices 8 and 9. It can also be charged. The operation of the signal lamp 51 and the like by the battery 10 and the charging of the battery 10 by the power generation devices 8 and 9 may be performed simultaneously.
Note that the DC power discharged from the battery 10 is converted into AC power by the inverter 44, and is transmitted to the devices 2, 3, 11, 12 and the signal lamp 51 in the traffic signal controller 1 via the second switching unit 42. Supplied.

  The battery 10 is a backup power source when the power of the commercial power source 7 should not be used for power saving or when the commercial power source 7 cannot be used due to a power failure. The battery 10 includes a secondary battery such as a lead storage battery, a lithium ion battery, a nickel cadmium battery, or a nickel metal hydride battery. The battery 10 may be built in the housing of the traffic signal controller 1 or may be provided separately outside the housing.

  The battery 10 includes a charge / discharge control unit 10a, and the charge / discharge control unit 10a performs charge control, control for overcharge protection, and control for overdischarge protection. The charging / discharging control unit 10a stops charging the battery 10 when the battery 10 is fully charged (a state in which the predetermined charging reference amount is reached). When there is power supply to the battery 10 when it is not fully charged, the charge / discharge control unit 10a controls charging to the battery 10 according to a predetermined charge control procedure. In addition, the charge / discharge control unit 10 a outputs a signal indicating the charge amount of the battery 10 to the power supply control unit 43.

[Power control processing]
Since the battery 10 is a backup power source at the time of power saving or power failure, when the commercial power source 7 is available, the battery 10 is kept in a sufficiently large state (fully charged), and the state is maintained. It is desirable to prepare for power saving or power outage. That is, the second driving mode in which the signal lamp 51 or the like is driven by the battery 10 and the power of the battery 10 is discharged is when power saving is necessary or when the commercial power supply 7 is cut off and a power failure occurs. The basic idea is that it should be restricted when the use of the commercial power source 7 is restricted.

However, if the battery 10 is fully charged, even if the power generators 8 and 9 using natural energy such as the solar battery 8 and the wind power generator 9 generate power, the battery 10 cannot store any more power.
Therefore, the power supply control unit 43 of the present embodiment does not switch to the second drive mode in which the signal lamp 51 or the like is driven by the battery 10 only during power saving or power failure, but when the commercial power supply 7 can be used. If the predetermined condition is satisfied, the signal lamp 51 is switched to the second drive mode in which the battery 10 is driven. Thereby, the electric power of the battery 10 is discharged, and there is room for storing the electric power generated by the power generation devices 8 and 9 using natural energy in the battery 10. Moreover, since the signal lamp 51 and the like can be driven by the power discharge of the battery 10, the power use of the commercial power supply 7 can be suppressed accordingly.
Note that the switching of the signal lamp 51 and the like to be driven by the battery 10 for power saving may be performed in response to a command from the central device 1 (command to drive the battery for power saving) or a traffic signal. It may be triggered by the fact that it has been detected that it is time to save power by the timer of the controller 1.

2 shows a flowchart of a first process of power control performed by the power control unit 43 (switching process of the first switching unit), and FIG. 3 shows a second process of power control performed by the power control unit 43 (first process). 2 is a flowchart of switching processing of the two switching units.
2 and 3 are periodically executed. 2 and 3 may be performed by the charge / discharge control unit 10a of the battery 10.

  In the first process of the power supply control in FIG. 2, first, it is determined whether or not the amount of power generated by the power generation devices 8 and 9 exceeds a predetermined charge switching reference value (first threshold) (step S1). . The power supply control unit 43 makes a determination based on the power generation amount output from the power generation meter 20. The charge switching reference value is a value indicating a sufficient power generation amount for charging the battery 10.

  When the amount of power generated by the power generation devices 8 and 9 is less than the charge switching reference value due to bad weather or no wind, the power supply control is performed so that the battery 10 is charged by the commercial power supply 7. The unit 43 switches the first switching unit 41 to the commercial power supply 7 side to enter the first charging mode (step S2). In the first mode, when power is supplied from the commercial power source 7 to the battery 10 and the battery 10 is fully charged, charging is stopped by the charge / discharge control unit 10a.

  When the amount of power generated by the power generation devices 8 and 9 exceeds the charge switching reference value due to a clear sky or when the wind is blowing, the battery 10 is charged by the power generation devices 8 and 9. Moreover, the power supply control unit 43 switches the first switching unit 41 to the power generation devices 8 and 9 side to enter the second charging mode (step S3).

  In the second process (partial discharge process) of the power supply control in FIG. 3, first, it is determined whether or not the battery 10 is fully charged (a state in which a predetermined charge reference amount has been reached) (step S41). The power supply control unit 43 determines whether or not the battery is fully charged based on the signal indicating the amount of charge output from the charge / discharge control unit 10a.

If the battery 10 is not fully charged, the partial discharge process is terminated, and if it is fully charged, the process proceeds to the next step S42.
Note that the process shift to step S42 is not limited to the case where the battery 10 is fully charged, and may be performed when the battery 10 has reached a predetermined charging reference amount. The predetermined charge reference amount is preferably a charge amount that can be evaluated as being almost fully charged (for example, a charge amount of about 99% or 98% of full charge).
If partial discharge is performed when the battery charge is low, it takes a very long time to recharge, and it is sufficient when there is a situation where battery operation is required, such as during power saving or power outage. The amount of charge may not be secured. On the other hand, if partial discharge is performed when the battery charge is almost full, even when a situation where battery driving is required, such as during power saving or power outage, occurs. It is easy to ensure a sufficient amount of charge.

  In step S42, it is determined whether or not the power generation amount of the power generation devices 8 and 9 exceeds a predetermined power generation reference amount (second threshold). This power generation reference amount is a value indicating a sufficient power generation amount to be recharged by the power generation devices 8 and 9 even if the power is partially discharged from the battery 10. The power generation reference amount may be the same value as the charge switching reference value described above, or may be a different value.

  When the power generation amount of the power generation devices 8 and 9 is less than the power generation reference amount, it is considered that if the battery 10 is discharged, recharging with natural energy is hindered, and the battery 10 is not partially discharged. The discharge process ends. When the power generation amount of the power generation devices 8 and 9 exceeds the power generation reference amount, the process proceeds to the next step S43.

  In step S43, in order to determine the discharge amount due to partial discharge, the power generation amount of the power generation devices 8, 9 and a predetermined threshold value (third threshold value; third threshold value> power generation reference amount (second threshold value)) , Compare. When the amount of power generated by the power generation devices 8 and 9 is relatively large (when the weather is fine or during strong winds), reliable recharging can be expected even if the battery 10 is discharged a lot. On the other hand, when the amount of power generated by the power generators 8 and 9 is relatively small (during cloudy weather or light wind), recharging can be performed more reliably by reducing the discharge of the battery 10.

  Therefore, when it is determined in step S43 that the power generation amount is equal to or greater than the predetermined threshold, a discharge up to 90% of the charge amount (a relatively large discharge amount) is determined as the discharge amount (step S44). On the other hand, if it is determined in step S43 that the power generation amount is less than the predetermined threshold value, a discharge up to 95% of the charge amount (a relatively small discharge amount) is determined as the discharge amount (step S45). In steps S43 to S45, one of the two types of discharge amounts is determined, but there may be three or more candidates for the determined discharge amount. Further, instead of selecting from a plurality of discharge amount candidates, the discharge amount may be determined based on an arithmetic expression for calculating the discharge amount from the power generation amount.

  When the amount of discharge is determined, the power supply control unit 43 switches the second switching unit 42 to the battery 10 side to enter the second drive mode in which the signal lamp 51 and the like are driven by the battery 10 (step S46). Thereby, the partial discharge of the battery 10 is performed and the charge amount is reduced.

  The power supply control unit 43 repeats the processing from step S42 to step S47 until the discharge amount determined in steps S44 and S45 is reached (step S47). Note that only step S47 may be repeated until the determined discharge amount is reached, but when the power generation amount of the power generators 8 and 9 varies during partial discharge by repeating the processing of step S42 to step S47. In addition, it becomes possible to change to an appropriate discharge amount.

  The management of the discharge amount by the power supply control unit 43 may be performed based on a signal indicating the discharge amount output from the charge / discharge control unit 10a, or simply the discharge time without directly monitoring the discharge amount. (The discharge amount increases according to the discharge time).

  When the partial discharge up to the determined discharge amount is completed, the power supply control unit 43 switches the second switching unit 42 to the commercial power supply 7 side and returns to the first drive mode in which the signal lamp 51 and the like are driven by the commercial power supply 7. . Thereby, the partial discharge of the battery 10 is stopped, and then recharging is performed. Since discharge was performed when the power generation amount of the power generation devices 8 and 9 using natural energy was sufficiently large, it can be expected that the subsequent recharging is also performed from the power generation devices 8 and 9 using natural energy ( (See FIG. 2).

Therefore, the opportunity to store the electric power generated by the power generation devices 8 and 9 using natural energy increases, and waste can be reduced.
Moreover, since the power generation amount of the power generation devices 8 and 9 is discharged only when it is at a level at which recharging can be immediately performed, it can be expected that the power generation devices 8 and 9 will immediately return to full charge even when discharged. It has little effect on the backup function at the time of power saving or power failure.

In the case of the battery 10 that can be charged at the same time as discharging, even if the battery 10 is being partially discharged, if the first switching unit 41 is switched to the battery 10 side, the partial discharge is not completed. Is also charged. As a result, when the power generation amount of the power generation devices 8 and 9 using natural energy is greater than or equal to the power consumption by the signal lamp 51 or the like, the loop from step S42 to step S47 in FIG. It becomes possible to operate without using power.
In addition, even if the power generation amount of the power generation devices 8 and 9 using natural energy is unexpectedly reduced during recharging after partial discharge, charging from the commercial power supply 7 is possible. Charging itself is possible.

[Modified example of partial discharge treatment]
FIG. 4 shows a modification of the partial discharge process shown in FIG. In step S43 in FIG. 3, the power generation amount of the power generation devices 8 and 9 is compared with a predetermined threshold value (third threshold value) in order to determine the discharge amount. In step S43 in FIG. Is not directly considered, but whether or not partial discharge is to be performed is determined based on information on factors that affect the amount of power generated by the power generation devices 8 and 9.

Since it takes a certain amount of time to discharge and recharge, even if the current power generation level is sufficient, it is not always possible to maintain a sufficient level of power generation until recharging is complete. .
For example, in the case of a solar cell, since the amount of power generation depends on the amount of solar radiation, a sufficient amount of power generation cannot be expected in a time zone where the amount of solar radiation is small (typically at night). Therefore, even if the current power generation amount is sufficient, if the sunset is near, the power generation amount may decrease before recharging is completed. Therefore, it is better to determine whether or not to execute partial discharge in consideration of not only the current power generation amount but also the future power generation amount.

  Therefore, for example, in step S43 in FIG. 4, it is determined whether or not the current time is “two hours or more of sunset”. % Discharge is determined (step S44), and if it is not “two hours or more of sunset”, the partial discharge process is terminated without performing the partial discharge.

In this way, more reliable recharging can be performed by determining whether or not to perform partial discharge based on information related to factors that affect the amount of power generation (time information). That is, since the power generation amount of solar power generation is influenced by the state of solar radiation, the amount of discharge can also be adjusted so as not to cause overdischarge if it is adjusted based on information related to solar radiation.
In addition, when determining the presence or absence of solar radiation, rather than simply determining by time, for example, the installation position and height of the solar cell, the position and height of the building around the solar cell, the relationship between the date and the position of the sun, You may consider whether a solar cell does not enter a shadow, combining information, such as the present date. Moreover, when determining the presence or absence of solar radiation, you may consider weather information (weather forecast information).

Further, the information relating to the factor affecting the power generation amount may be past statistical data such as the average solar radiation amount and the average wind speed in each season of spring, summer, autumn and winter. For example, a time zone in which the power generation amount is equal to or greater than a predetermined threshold value is specified based on statistical data, and partial discharge may be performed if the current time is within the time zone.
Moreover, when the power supply control process for partial discharge is not frequently performed, the average solar radiation amount or average for each predetermined period (such as one or a plurality of hours, one or a plurality of days, one or a plurality of months). If the wind speed is equal to or higher than a predetermined threshold, partial discharge may be performed.

  In FIG. 4, the partial discharge process was completed without performing partial discharge unless it was “two hours or more of sunset”. However, based on information on factors affecting future power generation amount. The discharge amount may be adjusted.

[Appendix]
The embodiment disclosed this time (including the above-described modifications) is illustrative in all respects and not restrictive. The scope of the right of the present invention is not the embodiment described above, but includes all modifications within the scope equivalent to the scope of the claims.

1 Traffic Signal Controller 4 Power Supply Unit 7 Commercial Power Supply 8 Solar Cell (Power Generator)
DESCRIPTION OF SYMBOLS 9 Wind power generator 10 Battery 10a Charging / discharging control part 20 Power generation meter 41 1st switching part 42 2nd switching part 43 Power supply control part (control part)
51 Signal lamp

Claims (5)

A traffic signal controller for controlling the timing of switching the color of a signal lamp,
A battery that can be charged from a commercial power source and a power generation device that generates power using natural energy, and configured to be switched to either the commercial power source or the battery as a power source for driving the signal lamp, and charging the battery Regardless of which of the commercial power supply and the power generator is selected as the power supply source for the power supply, the commercial power supply can be selected as the power supply for driving the signal lamp,
A control unit that performs a partial discharge process for partial discharge that discharges a part of the charge amount of the battery until a predetermined discharge amount is reached;
In the partial discharge treatment, wherein, when the commercial power source is selected as the power source for the driving of the signal lamp device, the power generation amount by the power generator exceeds a predetermined power generation reference amount, the The battery is selected as a power source for driving the signal lamp and the partial discharge is performed. After the partial discharge is completed, the commercial power source is returned to the state selected as the power source for driving the signal lamp. Traffic signal controller. The said control part performs the said partial discharge, when the electric power generation amount by the said electric power generating apparatus exceeds predetermined electric power generation reference amount, and the charge amount of the said battery has reached predetermined electric charge reference amount. Traffic signal control machine. The traffic signal controller according to claim 1, wherein the control unit adjusts a discharge amount based on information on a power generation amount by the power generation device or a factor affecting the power generation amount by the power generation device. The power generation device includes a power generation device that performs solar power generation,
The traffic signal controller according to claim 3, wherein the information related to a factor affecting the amount of power generated by the power generation device includes information related to solar radiation. The traffic signal controller according to claim 2, wherein the charge reference amount is a charge amount when the battery is almost fully charged.

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