JP2013104277A - Blind control system, electric blind, battery device and repair method of blind control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a blind control system which can contribute to restraining a peak power demand by supplying power from batteries respectively mounted on many electric blinds to other electric devices other than the electric blinds.SOLUTION: A blind control system comprises: a central control device 8 which outputs to controllers of many electric blinds 1 a command signal for driving the electric blinds; batteries 9 mounted on respective electric blinds; DC power source wiring lines L3 which are connected to the respective batteries, for supplying power from the batteries to electric devices other than the electric blinds; and control means 2 and 8 which, during a period of a peak power demand, allow the batteries as power sources to operate the respective electric blinds, and allow the batteries to supply power to the electric devices other than the electric blinds through the DC power source wiring lines, and, during the period other than the peak power demand, allow a commercial AC power source to drive the electric blinds 1 and to charge the batteries 9.

Description

  The present invention relates to a blind control system that controls charging and discharging of a large number of small batteries and contributes to suppression of power demand peaks.

  Blinds are installed on each window in buildings with many windows such as high-rise buildings. In such a building, in order to control the operation of a large number of blinds, each blind and the central control device are connected by a communication system, and the operation of each blind is collectively performed based on a command signal output from the central control device. Some have a blind control system that controls them.

  Some blinds are equipped with a solar panel and a battery, and the power stored in the battery is used as needed to reduce power consumption or stabilize the operation during a power failure.

  In Patent Document 1, a battery stored by a solar battery is arranged for each of a plurality of blinds, and the blinds are driven using the battery as a power source as necessary, and the number of operable times according to the amount of stored electricity and the amount of power generation is displayed. An electric blind having a function of displaying on a screen is disclosed.

Patent Document 2 discloses an electric blind that includes a solar power generation unit and a rechargeable battery in one blind and operates using the rechargeable battery as a power source.
Patent Document 3 discloses an uninterruptible power supply device that supplies power from a plurality of power storage means to a plurality of devices according to the importance level in the event of a power failure by a demand control device.

  Patent Document 4 discloses a system for charging an electric vehicle battery using nighttime electric power and suppressing electric power demand peak using electric power stored in the electric vehicle battery at the time of electric power demand peak. .

JP 2011-74707 A JP 2010-150884 A JP 2004-328960 A JP 2007-282383 A

  In recent years, there has been a demand for further suppressing the power demand peak in response to tight power supply and demand. In order to effectively suppress the power demand peak, it is necessary to supply the electric power stored in the battery at the time of non-peak power demand, such as at night, to a wide range of electrical equipment at the peak time.

In the electric blind disclosed in Patent Literature 1 and Patent Literature 2, a configuration for supplying electric power stored in the battery to a wide range of devices other than the blind is not disclosed.
In patent document 3, it is the structure which supplies electric power to a some apparatus from an electrical storage means at the time of a power failure, and the means for suppressing an electric power demand peak is not disclosed.

  Patent Document 4 does not disclose a control means for automatically supplying power stored in a battery to a power consumer at a power demand peak and storing the battery in a power demand non-peak. Moreover, since a commercial AC power supply is converted into a direct current by an inverter to charge the battery, and a direct current power stored in the battery is converted into an alternating current by an inverter and supplied to a power consumer, power efficiency is deteriorated.

  An object of the present invention is to provide a blind control system that can contribute to the suppression of power demand peaks by supplying electric power to batteries other than the electric blinds from batteries respectively provided in a large number of electric blinds. .

  In claim 1, a central control device that is connected to each of the electric blinds via a communication line and outputs a command signal for driving the electric blind to a controller of each electric blind, and is installed in each electric blind. A battery that is connected to each battery and supplies power from the battery to devices other than the electric blind, and the electric blind is connected to the battery in a peak power demand period of the commercial AC power supply. And the electric power of the battery is supplied to electric equipment other than the electric blind via the DC power supply wiring, and the electric blind is driven by the commercial AC power supply except during a power demand peak time period. And a control means for charging the battery.

  According to a second aspect of the present invention, the control unit includes at least one of the controller, the central control device, and an operation switch that outputs an operation signal for driving the electric blind to the controller.

  According to a third aspect of the present invention, the control unit includes a timer unit that generates time information, a storage unit that stores a time table of power demand, and a time zone of the power demand peak based on the time information and the time table. Determination means for determining whether or not there is.

According to a fourth aspect of the present invention, the electric blind is provided with a battery charging device that supplies a charging current to the battery from a power source other than the commercial AC power source.
According to a fifth aspect of the present invention, the battery charging device includes a solar cell panel attached to a solar shading material of the electric blind.

According to a sixth aspect of the present invention, an inverter that converts a DC voltage into an AC voltage is connected to the DC power supply wiring, and the AC voltage is supplied from the inverter to the electric device as a power source.
According to claim 7, in the electric blind that operates by selecting one of a commercial AC power source and a battery, each electric blind is operated with the battery as a power source during a power demand peak period of the commercial AC power source. The electric blind is driven by the commercial AC power source except during a power demand peak time period, and control means for charging the battery is provided.

  In claim 8, the control means is a controller provided in the electric blind, a central control device that is connected to the controller via communication wiring, and outputs a command signal for driving the electric blind to the controller, At least one of an operation switch that outputs an operation signal for driving the electric blind to the controller is provided.

  According to a ninth aspect of the present invention, the control unit includes a timer unit that generates time information, a storage unit that stores a time table of power demand, and a time zone of the power demand peak based on the time information and the time table. Determination means for determining whether or not there is.

  In Claim 10, in the battery unit provided in the electric blind which operates by selecting any one of the commercial AC power supply and the battery, the battery installed in each of the many electric blinds, and from each of the batteries other than the electric blind DC power supply wiring capable of supplying power to the electrical equipment, charging operation to each battery, power supply operation for supplying power from each battery to the electrical equipment, and the battery from the battery And a control means for performing a power supply operation for supplying power to the electric blind.

  The central control device according to claim 11, wherein a battery provided in each of the plurality of electric blinds is connected by a DC power supply wiring, an electric device is connected to the DC power supply wiring through an inverter, and the operation of each electric blind is controlled. In addition, during the peak power demand period of the commercial AC power supply, each electric blind is operated using the battery as a power supply, and the electric power of the battery is supplied to the electric device via the DC power supply wiring and the inverter. Outside the peak demand period, the electric blind is driven by the commercial AC power source and a program for charging the battery is set.

  ADVANTAGE OF THE INVENTION According to this invention, the blind control system which can supply electric power to the electric equipment other than an electric blind from the battery with which each of many electric blinds was equipped, and can contribute to suppression of an electric power demand peak can be provided. .

It is a block diagram which shows a blind control system. It is a block diagram which shows the electric constitution of an electric blind. (A) (b) is a side view which shows the outline | summary of an electric solar radiation shielding apparatus. It is a front view which shows an electric horizontal blind. It is explanatory drawing which shows the electrical structure of an electric horizontal blind. It is a flowchart which shows operation | movement of a blind control system. It is a flowchart which shows operation | movement of a blind control system.

  Hereinafter, an embodiment embodying the present invention will be described with reference to the drawings. A large number of electric blinds 1 constituting the blind control system shown in FIG. 1 are respectively installed in a large number of windows of a high-rise building or the like.

  An operation switch 2 is connected to each electric blind 1. The operation switch 2 is provided with timer means for outputting an operation signal for operating each electric blind 1 and adding the time information at the time of the operation to the operation signal.

  The electrical configuration of each electric blind 1 will be described with reference to FIG. 2. The power supply circuit 3 is supplied with commercial power of AC 100V through the AC power supply wiring L1. The power supply circuit 3 converts an AC voltage into a DC voltage and supplies it to the controller 4 as a power source.

  The controller 4 operates based on a preset program and an operation signal input from the operation switch 2 or a command signal input from the central control device 8 to be described later, and operates the motor 5 that drives the solar shading material. Control. The controller 4 has a memory function and stores a time table of power demand at each time of day.

  When the electric horizontal blind shown in FIG. 3A is used as the electric blind 1, the slat 6 is moved up and down by the operation of the motor 5 and the angle is adjusted. When the electric roller blind shown in FIG. 3B is used as the electric blind 1, the screen 7 is moved up and down by the operation of the motor 5.

  The controller 4 is connected to the central control device 8 via a communication line L2. The central controller 8 has a function of collectively controlling each electric blind 1 by outputting a control signal to a large number of electric blinds 1 via the communication wiring L2.

The controller 4 outputs a charge signal or a discharge signal to the power supply circuit 3 based on an operation signal or a command signal input from the operation switch 2 or the central controller 8.
A battery 9 is connected to the power supply circuit 3, and a charge signal or a discharge signal is input from the controller 4. When a charging signal is input from the controller 4 to the power supply circuit 3 and the battery 9, a charging current is supplied from the power supply circuit 3 to the battery 9 to charge the battery 9.

On the other hand, when a discharge signal is input from the controller 4 to the power supply circuit 3 and the battery 9, DC power is supplied from the battery 9 to the controller 4 via the power supply circuit 3.
The battery 9 is connected to a DC power supply wiring L3, and an inverter 10 is connected to the DC power supply wiring L3. When a discharge signal is input to the battery 9 and the inverter 10, the DC voltage stored in the battery 9 is supplied to the inverter 10 through the DC power supply wiring L 3, converted into AC 100 V by the inverter 10, and so on. Supplied to other electrical equipment.

  A solar cell panel 11 is connected to the battery 9. This solar cell panel 11 is attached to the surface of each slat 12 and connected to the battery 9 disposed in the head box 13 when the electric blind 1 is the electric horizontal blind shown in FIG. Is done.

  When the electric blind 1 is the electric roller blind shown in FIG. 3 (b), the solar cell panel 11 is attached to the fabric surface on the outdoor side of the screen 7, and is disposed in the winding shaft or in the frame. 9 is connected.

  FIG. 4 shows an example of an electric horizontal blind used as the electric blind 1. Multiple slats 12 are suspended from the head box 13 so as to be movable up and down and adjustable in angle. In the head box 13, the power supply circuit 3, the controller 4, the motor 5, and the battery 9 are disposed.

  As shown in FIG. 5, AC 100V is supplied to the power supply circuit 3 through the AC power supply wiring L1, and is connected to the battery 9 through the connection wiring CL1. The power supply circuit 3 is connected to the controller 4 via the connection line CL2, and the controller 4 and the battery 9 are connected via the connection line CL3.

  The controller 4 controls the charging operation from the power supply circuit 3 to the battery 9, the discharging operation from the battery 9 to the power supply circuit 3, and the discharging operation from the battery 9 to the external device via the DC power supply wiring L3. . Further, the controller 4 controls the operation of the motor 5 via the connection wiring CL4.

  The controller 4 is connected to the communication interface 14 via a connection line CL5. The operation switch 2 is connected to the communication interface 14 and is also connected to the central control device 8 via the communication line L2. The operation switch 2 is supplied with power from the controller 4 through the connection wiring CL5 and the communication interface 14.

  Power is supplied to the operation switch 2 from the power supply circuit 3 via the controller 4. Further, a small capacity battery that can be charged by the controller 4 may be mounted on each operation switch 2 as a power source.

  The central control device 8 stores a time table of power demand at each time of the day, like the controller 4. Based on the time table, the central control device 8 outputs a command signal to the controller 4 of each electric blind 1 at the time of peak power demand, and from the battery 9 of each electric blind 1 to the DC power supply wiring L3 and the inverter 10. Power is supplied to other systems such as a lighting device of the high-rise building via the.

The blind control system as described above can be structurally realized by adding the following configuration to the conventional blind control system.
That is, the conventional blind control in which the operation of each electric blind 1 can be collectively controlled from the central control device 8 via the communication line L2, and the operation of each electric blind 1 can be controlled by the operation of the operation switch 2. A solar panel 11 and a battery 9 are added to each electric blind 1 for the system.

Further, power can be supplied from each battery 9 to another system such as a lighting device via the DC power supply wiring L3 and the inverter 10.
At the time of peak power demand, the motor 5 is driven by the power of the battery 9, and a program for controlling the power to be supplied from the battery 9 to another system is at least one of the controller 4, the operation switch 2, and the central controller 8. Prepare for crab. Further, a program for charging the battery 9 using AC 100 V as a power source is provided in at least one of the controller 4, the operation switch 2, and the controller 4 when the power demand is not peak.

Next, the operation of the blind control system configured as described above will be described with reference to FIGS.
In each electric blind 1, the electric power generated by the solar cell panel 11 is always stored in the battery 9. As shown in FIG. 6, when AC 100V is supplied to the power supply circuit 3, the operation of the controller 4 supplies a charging current to the battery 9 from the power supply circuit 3 to charge the battery 9, and the controller 4 operates The system waits for an operation signal from the switch 2 (steps 1 and 2).

When an operation signal is input from the operation switch 2, the controller 4 determines whether or not it is a power demand peak time zone based on the time information included in the operation signal (step 3).
If the input time of the operation signal is during the peak power demand period, the controller 4 determines whether or not the charge amount of the battery 9 is equal to or greater than a certain amount (step 4), and if the charge amount is sufficient. Then, the motor 5 is operated using the battery 9 as a power source (step 5), and for example, the raising / lowering operation or the angle adjustment operation of the slat 6 based on the operation signal is performed (step 6).

If the input time of the operation signal is not in the power demand peak time zone in step 3, the motor 5 is operated using AC 100V as a power source (step 7).
When the input of the operation signal is stopped, the process returns to step 1 and waits for the input of the next operation signal.

  The above operation is performed in parallel in each electric blind 1. Further, power is supplied from the battery 9 of each electric blind 1 to other lighting devices and the like at the time of peak power demand.

During a power failure, the controller 4 operates using the battery 9 as a power source, and can drive the slat 6 or the screen 7 by operating the operation switch 2.
FIG. 7 shows a case where the operation switch 2 has a function of determining whether or not it is a power demand peak time zone based on the time information and the power demand time table and outputting the determination signal to the controller 4. The operation is shown.

  The operation switch 2 always outputs the determination signal to the controller 4. At the time of peak power demand, the controller 4 enters a state of operating with the battery 9 as a power source (steps 11 and 12), and determines whether or not the charge amount of the battery 9 is equal to or greater than a certain amount (step 13). And when the charge amount of the battery 9 is more than a fixed amount, it transfers to step 14 and will be in the state which waits for the operation signal from the operation switch 2 (steps 11-14).

  In step 11, when the power demand is not at a peak, the controller 4 is operated by the power source circuit 3 using AC 100V as a power source (step 15). Then, a charging current is supplied from the power supply circuit 3 to the battery 9 to charge the battery 9 (step 16), and the process proceeds to step 14.

If the charge amount of the battery 9 is not sufficient in step 13, the process proceeds to step 16, and the process proceeds to step 14 while charging the battery 9.
In step 14, when an operation signal is input from the operation switch 2, it is determined whether or not the charge amount of the battery 9 is equal to or greater than a predetermined amount (step 17). If the charge amount of the battery 9 is equal to or greater than a certain amount, the process proceeds to step 18 where the controller 4 drives the motor 5 using the battery 9 as a power source, and for example, moves up and down or adjusts the angle of the slat 6 based on the operation signal. An operation is performed (step 19).

  If the charged amount of the battery 9 is not sufficient in step 17, the process proceeds to step 20, where the controller 4 enters a state of driving the motor 5 with AC 100V as a power source, and the process proceeds to step 19.

The blind control system configured as described above can obtain the following operational effects.
(1) At the time of peak power demand, the motor 5 can be driven using the battery 9 of each electric blind 1 stored during the non-peak power demand as a power source. Moreover, at the time of peak power demand, power can be supplied from the battery 9 of each electric blind 1 to another system such as a lighting device. Therefore, the power demand peak can be suppressed.
(2) The battery 9 can be charged with electric power output from the solar cell panel attached to the slat 6 or the screen 7.
(3) Based on the time information added to the operation signal output from the operation switch 2 to the controller 4 and the time table of the power demand stored in the controller 4, it is determined whether or not it is at the time of peak power demand. can do.
(4) Based on the determination signal output from the operation switch 2 to the controller 4, it can be determined whether or not the controller 4 is at a power demand peak time.
(5) During a power failure, the slat 12 or the screen 7 can be operated using the battery 9 as a power source.
(6) Since power is supplied from the batteries 9 provided in each of the many electric blinds 1 to the other systems via the DC power supply wiring L3 and the inverter 10, even if the capacity of the battery 9 of each electric blind 1 is reduced, As a whole, sufficient battery capacity can be secured. Therefore, a sufficient battery capacity can be ensured without concentrating a large capacity battery in one place, so that safety can be improved.
(7) Compared to the conventional blind control system, the electric blind 1 is provided with a battery 9 and a solar battery panel 11, and the power of the battery 9 can be supplied to other systems via the DC power supply wiring L3 and the inverter 10. At least one of the controller 4, the operation switch 2, and the central control device 8 is controlled to drive the motor 5 with the power of the battery 9 and supply power from the battery 9 to another system at the time of peak power demand. The program to do. In addition, a program for charging the battery 9 using 100 VAC as a power source is provided when the power demand is not peak. Then, the blind control system of this embodiment can be comprised using the conventional electric blind.

You may implement the said embodiment in the following aspects.
-In addition to the solar panel, the battery may be charged using a cogeneration system.
In step 11 shown in FIG. 7, the controller 4 is provided with timer means for generating time information and a time table for power demand at each time of day, and the controller 4 determines whether or not it is a power demand peak time zone. You may judge.
As the electric blind, various electric solar shading devices such as an electric scooping curtain and an electric pleated curtain may be used in addition to the electric horizontal blind and the electric roll blind.

  DESCRIPTION OF SYMBOLS 1 ... Electric blind, 2 ... Control means, storage means, determination means (operation switch), 3 ... Power supply circuit, 4 ... Control means, storage means, determination means (controller), 5 ... Motor, 8 ... Control means, storage means Determination means (central control device), 9 ... battery, 10 ... inverter, 11 ... battery charging device (solar cell panel), L1 ... AC power supply wiring, L2 ... communication wiring, L3 ... DC power supply wiring.

Claims (11)

A central control device that is connected to a number of electric blinds via a communication line and outputs a command signal for driving the electric blinds to a controller of each electric blind;
A battery installed in each electric blind;
DC power supply wiring connected to each battery and supplying power from the battery to devices other than the electric blinds;
In the peak power demand time of the commercial AC power supply, each electric blind is operated using the battery as a power supply, and the electric power of the battery is supplied to an electric device other than the electric blind via the DC power supply wiring. A blind control system comprising: control means for driving the electric blind with the commercial AC power source and charging the battery except during a demand peak time period. The control means includes
The blind control system according to claim 1, further comprising: at least one of the controller, the central control device, and an operation switch that outputs an operation signal for driving the electric blind to the controller. The control means includes
Timer means for generating time information;
Storage means storing a time table of power demand;
3. The blind control system according to claim 1, further comprising: a determination unit configured to determine whether or not the power demand peak time period is based on the time information and the time table.   4. The blind control system according to claim 1, wherein the electric blind is provided with a battery charging device that supplies a charging current to the battery from a power source other than the commercial AC power source. 5.   The blind control system according to claim 4, wherein the battery charger includes a solar battery panel attached to a solar shading material of the electric blind.   6. The DC power supply wiring according to any one of claims 1 to 5, wherein an inverter that converts a DC voltage into an AC voltage is connected to the DC power supply wiring, and an AC voltage is supplied from the inverter to the electric device as a power source. The blind control system described. In electric blinds that operate by selecting either commercial AC power or battery power,
The electric blind is operated using the battery as a power source during a power demand peak time of the commercial AC power source, and the electric blind is driven by the commercial AC power source during a time other than the power demand peak time period. An electric blind comprising control means for charging. The control means includes
A controller provided in the electric blind, a central controller connected to the controller via communication wiring, and outputting a command signal for driving the electric blind to the controller, and for driving the electric blind to the controller The electric blind according to claim 7, wherein the electric blind is provided in at least one of an operation switch for outputting an operation signal. The control means includes
Timer means for generating time information;
Storage means storing a time table of power demand;
9. The electric blind according to claim 7, further comprising: a determination unit that determines whether or not the power demand peak time period is based on the time information and the time table. In a battery unit equipped with an electric blind that operates by selecting either a commercial AC power source or a battery power source,
A battery installed in each of a number of electric blinds;
DC power supply wiring capable of supplying power from each battery to electric devices other than the electric blinds;
Control means for performing a charging operation to each battery, a power supply operation for supplying power from each battery to the electric device, and a power supply operation for supplying power from the battery to the electric blind provided with the battery. And a battery device.   A battery provided in each of the many electric blinds is connected by a DC power supply wiring, an electric device is connected to the DC power supply wiring via an inverter, and a central control device that controls the operation of each electric blind is connected to a commercial AC power supply. In the power demand peak time zone, the electric blinds are operated using the battery as a power source, and the power of the battery is supplied to the electric device via the DC power supply wiring and the inverter. In other cases, the electric blind is driven by the commercial AC power source and a program for charging the battery is set.