JP6057604B2 - Power supply control device - Google Patents

Description

  The present invention relates to an apparatus for controlling power supply by a commercial power supply and an auxiliary power supply apparatus.

  As a simple auxiliary power supply that can be used even in homes that do not have a private power generation system such as solar power generation, it is possible to charge the storage battery by receiving power from a commercial power supply, and the direct current power discharged from the storage battery An auxiliary power supply device having a function of converting to electric power and outputting the electric power is known.

FIG. 10 shows a usage example of this type of auxiliary power supply device 300.
200 in the figure is a distribution board installed in a house, and is provided with a main breaker 201 (leakage breaker) and a plurality of safety breakers 202 (wiring breaker). Electric power from the commercial power source is supplied to each safety breaker 202 via the main breaker 201 and is distributed to each load system. Each load system includes an outlet 203 and a lighting socket 204, to which predetermined load devices are connected.

As shown in FIG. 10A, the auxiliary power supply device 300 is connected to one of the outlets 203 and charged.
When a power failure occurs in the commercial power supply, all the power supply from the breakers 201 and 202 to the load system is stopped. However, as shown in FIG. 10 (2), by connecting the auxiliary power supply device 300 to an important load device, Power can be supplied to the load equipment.

  In addition, as shown in FIG. 11, if the auxiliary power supply 300 is connected to the power supply line in the distribution board 200, it is possible to supply power to all the load systems and operate each load device.

  In Patent Document 1 below, a second distribution board (attached distribution board) is provided between the system power supply (synonymous with commercial power supply) and the distribution board in the home. A power supply system having a configuration in which an external power source such as a portable rechargeable battery having an inverter or an electric vehicle is connected is disclosed. The system power supply and each distribution board are connected by three power lines, but each distribution board is provided with a main switch for each power line. After the main switch in the attached distribution board, an emergency power supply is connected to two of the three power lines via an earth leakage breaker (breaker). An emergency outlet is connected to the two power lines corresponding to 1 through the earth leakage circuit breaker. Normally, all main switches are closed and power is supplied to all load systems, and charging is performed by an external power source. In the event of a power failure, only the power line connected to the emergency power supply is enabled by operating the manual switch, and the power from the external power supply is supplied to the domestic distribution board via the load distribution board and connected to the emergency outlet. Only the important load is supplied.

JP 2010-172068 A

  In the method shown in FIG. 10 (2), only a specific load device can be moved, which is not convenient. On the other hand, as shown in FIG. 11, when the electric power generated by the discharge from the auxiliary power supply device 300 is supplied to the distribution board 200, the electric power is also supplied to the load system that does not need to supply the electric power. In addition, as shown by the dotted line in FIG. 11, a phenomenon (reverse power flow) in which a current due to discharge flows from the distribution board 200 to the outside occurs, and all of the stored electric power cannot be used. The efficiency is very bad.

  According to the power feeding system described in Patent Document 1, it is possible to supply power from an external power source only to a load system connected to two emergency power lines out of three power lines during a power failure. However, since the supply destination of the emergency power supply is determined by the wiring, it is difficult to freely change the target of the emergency power supply. Also, in the system of Patent Document 1, a reverse power flow at the time of discharging from an external power source should occur, but there is no description in Patent Document 1 regarding means for preventing it.

  The present invention has been made paying attention to the above-mentioned problems. When power is supplied by discharge from an auxiliary power supply device in the event of a power failure of a commercial power supply, the user can freely select the load system of the supply destination. In addition, it is an object to prevent a reverse power flow to the outside from being generated by the discharge from the auxiliary power supply device.

A power supply control device according to the present invention controls power supply to a plurality of load systems from a general distribution board that receives power supply from a commercial power supply and an auxiliary power supply device having a charging function from the commercial power supply and a photovoltaic power generation module. A plurality of breakers connected to the auxiliary power supply line by the auxiliary power supply device, a number of switching units corresponding to these breakers, a control unit for individually controlling the operation of each switching unit, and its control And an operation unit for setting the contents of.

Each switching unit, the plurality of breakers of one of one of the general distribution board multiple breakers within, connect either a breaker specified by the control unit to the load system. The control unit is provided with the following control circuit, conversion circuit, power failure detection circuit, and power supply switching circuit .

Together contain a memory in which information for identifying the switching unit corresponding to the priority load system to be supplied with priority an auxiliary power during a power outage of the commercial power source is registered in the control circuit, the switching control means and the registration information will be described later Update means are provided. The conversion circuit converts 100V AC supplied from a commercial power supply or an auxiliary power supply device into a DC voltage having a magnitude for driving the control circuit, and supplies the DC voltage to the control circuit. The power failure detection circuit detects a commercial power failure from the general distribution board. The power supply switching circuit is connected to the commercial power supply, the auxiliary power supply device, and the power failure detection circuit, and the commercial power supply is connected to the conversion circuit during an off state in which the detection signal from the power failure detection circuit does not indicate a power failure of the commercial power supply, The power source connected to the conversion circuit is switched from the commercial power source to the auxiliary power source in response to the detection signal switching from the off state to the on state indicating a power failure of the commercial power source. The switching control means of the control circuit inputs a detection signal from the power failure detection circuit, and in response to the change of the detection signal from the off state to the on state, based on the information registered in the memory, Specify that the breaker on the auxiliary power supply side is connected to the priority load system in the switching unit, and specify that the breaker in the general distribution board is connected to the load system in the switching unit for other load systems . The registered information update means, when an operation for specifying a priority load system is performed on the operation unit, information for identifying a switching unit corresponding to the priority load system registered in the memory based on the specified content Update.

  The power supply control device having the above configuration is used by being incorporated in a power supply system that has already been built in a building such as a house. The auxiliary power supply device is, for example, a type of device that is charged by directly receiving commercial power from a general distribution board. However, the auxiliary power supply device is not limited thereto, and has a power generation function such as solar power generation. You may use the auxiliary power supply device of the type which stores the produced | generated electric power.

  The switching unit of the power supply control device described above includes a load system to be subject to power supply control in the existing power supply system, a breaker in the general distribution board that was originally connected to the load system, and an auxiliary power supply in the own device. Connect to the breaker specified by the control unit among the breakers receiving the supply. When the specified content of the control unit changes, the breaker to be connected is also switched.

The control circuit of the power supply control device can normally specify that the breaker in the general distribution board is connected to the load system to each switching unit with the commercial power supply as the driving power supply. If the power failure to the commercial power supply occurs, the driving power source of the control circuit by the power supply switching circuit is switched to the auxiliary power supply, by designation from the control circuit based on the information registered in the memory, the switching unit for the priority load system only the connection destination to the priority load system is switched to the breaker of the auxiliary power supply side. Thereby, the connection destination to the priority load system is switched to the breaker on the auxiliary power source side and the auxiliary power is supplied, but the other load systems are in a power failure state.

The priority load system can be freely selected by a designated operation on the operation unit, and can be changed as appropriate. Therefore, the priority load system can be flexibly adapted to the type of existing load system and the charging capacity of the auxiliary power supply. Selection becomes possible. In addition, the power feed path from the breaker in the general distribution board and the power feed path from the breaker on the auxiliary power supply side are insulated across the switching unit, and the control unit also uses the power switching circuit to connect between the commercial power supply and the auxiliary power supply. Is insulated, there is no risk of reverse power flow to the commercial power source even if power from the auxiliary power supply flows through the load system during a commercial power failure.
Therefore, power can be supplied only to the selected priority load system, and loss due to reverse power flow can be prevented, and convenience and power supply efficiency are improved.

In the power supply control device according to the embodiment, the operation unit can receive an operation for designating a time zone for supplying power from the auxiliary power supply device for each load system in a state where the commercial power supply is not interrupted. In accordance with the above operation, the control circuit stores schedule information that associates the switching unit connected to the load system designated to perform power feeding from the auxiliary power supply and the designated time zone for power feeding. A schedule registration means for registering the timer and a timer for measuring the time.

Furthermore, the switching control means of this embodiment is provided for each designated time zone of power supply based on the time measured by the timer and the schedule information in the memory while the detection signal from the power failure detection circuit is maintained in the off state. The switch for the load system for which the time zone is specified specifies that the auxiliary power source side breaker is connected to the load system, while the switch for the other load system has a breaker on the general distribution board side. To connect to the load system.

  According to the above-described embodiment, even when the commercial power supply is not interrupted, it is possible to supply power to the desired load system from the auxiliary power supply as necessary. Therefore, convenience is further improved.

By incorporating the power supply control device of the present invention into an existing power supply system, the priority load system for supplying power from the auxiliary power supply device in the event of a power failure of the commercial power supply can be selected or changed by a designated operation on the operation unit Is possible. Therefore, regardless of the existing power distribution configuration and the type of load system, the load system that supplies power when the commercial power supply is interrupted can be freely selected, and convenience is improved.
Moreover, since there is no possibility that a reverse power flow to the commercial power supply side is caused by the power from the auxiliary power supply device, the power supply efficiency by the auxiliary power supply can be increased.

It is explanatory drawing which shows the structural example of the electric power feeding system by which the electric power feeding control apparatus by this invention was introduced. It is explanatory drawing which shows the example of the change of the electric power feeding state which arises with the power failure of a main power supply. It is a wiring diagram of a power feeding control device and a general distribution board. It is a block diagram which shows the structure of a main control board. It is a figure which shows an example of the screen for a setting displayed on a console. It is a flowchart of the process (normal process) which an arithmetic control part performs for electric power feeding control. It is a flowchart of the process (process at the time of a power failure) which an arithmetic control part performs for electric power feeding control. It is a figure which shows the example of the screen showing the use condition of an auxiliary power supply device. It is explanatory drawing which shows the example which introduced the electric power feeding control apparatus into the electric power feeding system containing a solar power generation system. It is explanatory drawing which shows the prior art example of the electric power feeding system containing a solar power generation system. It is explanatory drawing which shows the usage example of the conventional auxiliary power supply device. It is explanatory drawing which shows the prior art example which connects an auxiliary power supply device to a distribution board, and supplies electric power.

FIG. 1 shows a configuration example of a power supply system in which a power supply control device according to the present invention is introduced.
The power supply control device 1 of this embodiment is provided at a suitable location in a house together with an existing distribution board 2 (hereinafter referred to as “general distribution board 2”) installed in the house, and is equipped with various load systems. The power supply to the is controlled. A commercially available auxiliary power supply 3 is provided in the house.

The general distribution board 2 is for supplying commercial power, and includes a main breaker 20 and a plurality of safety breakers 21.
The power supply control device 1 is positioned as a second distribution board attached to the general distribution board 2. In addition to the main breaker 10 and the plurality of safety breakers 11, a number of electromagnetic relays 12 corresponding to the safety breakers 11 are provided. A relay control board 13 for controlling the operation of these electromagnetic relays 12, a main control board 14 for controlling the entire apparatus and setting related to the control contents are provided. The control unit of the power supply control device 1 includes a main control board 14 and a relay control board 13.

In FIG. 1, the power supply line of the commercial power source is indicated by a one-dot chain line and the power supply line of the auxiliary power source is indicated by a dotted line. In FIG. 3 to be referred to later, each power supply line is clearly shown in the same manner.
Hereinafter, the safety breaker 21 in the general distribution board 2 is referred to as “commercial power supply side breaker 21”, and the safety breaker 11 in the power supply control device 1 is referred to as “auxiliary power supply side breaker 11”. Further, the electromagnetic relay 12 in the power supply control device 1 is simply referred to as “relay 12”.

  As indicated by the one-dot chain line, commercial power is supplied to the auxiliary power supply device 3 from one of the commercial power supply side breakers 21 in the general distribution board 2. A switch 30 by an electromagnetic relay is provided in this supply path. The switch 30 is provided for the purpose of periodically switching between opening and closing of the commercial power supply. However, when the auxiliary power supply 3 has a function of controlling the charging time by a timer, the switch 30 is not provided. Also good.

  The auxiliary power supply device 3 has a function of converting alternating current of commercial power into direct current and charging, and a function of converting charged direct current power into alternating current and discharging. As indicated by the dotted line, the power (auxiliary power) generated by the discharge from the auxiliary power supply device 3 is supplied to the main breaker 10 and the main control board 14 of the power supply control device 1, and further from the main breaker 10 to each auxiliary power supply side breaker. 11. The main control board 14 is also supplied with commercial power from the main circuit breaker 20 in the general distribution board 2. However, the connection destination of the main control board 14 is not limited to the main circuit breaker 20, and the main power circuit breaker 21 is connected to the main power circuit board. You may connect to one.

  Each relay 12 in the power supply control device 1 is connected to one of a plurality of load systems 51, 52, 53,... And one of the auxiliary power source side breakers 11 of the own device and the commercial power supply of the general distribution board 2. Corresponding to one of the side breakers 21, one of these two breakers 11, 21 is connected to the load system. The relay control board 13 controls the operation of each relay 12 by an individual control signal (hereinafter referred to as “relay control signal”) under the instruction from the main control board 14. The switching operation of the switch 30 provided in the power supply line to the auxiliary power supply device 3 is similarly controlled by a relay control signal from the relay control board 13.

  FIG. 2 shows the power supply state generated by the power failure of the commercial power supply for the three load systems 51, 52, and 53 (here, “system 1”, “system 2”, and “system 3”) shown in FIG. An example of the change is shown.

The upper part of the figure is the normal power supply state. All the systems are connected to the commercial power source side breaker 21 and can be supplied with commercial power to operate the load equipment to which they belong.
When the commercial power supply fails, as shown in the lower part of FIG. 2, the system 1 and system 3 set as the priority load system are connected to the auxiliary power source side breaker 11, but the system 2 that is not the priority load system is The power supply side breaker 21 remains connected. Therefore, in the system 1 and the system 3, the load device can be operated by receiving the supply of the auxiliary power via the auxiliary power source side breaker 11, but the load device of the system 2 is stopped.

FIG. 3 shows specific examples of configurations and wiring states of the power supply control device 1 and the general distribution board 2.
A single-layer two-wire power supply line is applied to the commercial power supply and auxiliary power supply of this embodiment. In FIG. 3, each load system is indicated by an outlet in each system. Reference numeral 5 </ b> A is assigned to an outlet connected to the relay 12 of the power supply control device 1, and reference numeral 5 </ b> B is assigned to an outlet not connected to the relay 12. , 5C.

  In the power supply control device 1 in the example of FIG. 3, six relays 12 and six auxiliary power source side breakers 11 are introduced. The general distribution board 2 is provided with more commercial power source side breakers 21 (eight in the illustrated example) than the auxiliary power source side breakers 11, and six of them are in a one-to-one relationship with the relay 12 of the power supply control device 1. Connected with The two commercial power supply side breakers 21 not connected to the relay 12 are directly connected to the load system (outlets 5B and 5C), respectively, and one of them (outlet 5B) is connected to the power supply line to the auxiliary power supply 3. The number of relays 12 and auxiliary power supply side breakers 11 is not limited to six, and can be increased or decreased according to the number of load systems.

  Each relay 12 of this embodiment is a two-pole, two-phase type hinge-type relay, a load system is connected to the c contact, a commercial power source side breaker 21 of the general distribution board 2 is connected to the b contact, and the a contact is connected to the a contact. An auxiliary power supply side breaker 11 is connected. When the coil of the relay 12 is demagnetized, the load system is connected to the commercial power supply side breaker 21, but when the coil is excited, the connection destination of the load system is switched to the auxiliary power supply side breaker 11.

The relay control board 13 and each relay 12 are connected to each other via two signal lines. A DC voltage of a certain level is transmitted from one of the two signal lines, and the relay control signal described above is transmitted from the other signal line.
The DC voltage is always applied to one end of the coil of the relay 12. The relay control signal normally connects the commercial power supply side breaker 21 to the load system by applying the same voltage to both ends of the coil to demagnetize the coil. The state of the relay control signal at this time is hereinafter referred to as “commercial power supply designation state”.

  When the commercial power supply fails, the relay control signal for the relay 12 connected to the priority load system is switched, current flows through the coil, and the connection destination to the priority load system is switched from the commercial power source side breaker 21 to the auxiliary power source side breaker 11. . The state of the relay control signal at this time is hereinafter referred to as “auxiliary power supply designation state”.

  Even when the commercial power supply is not interrupted, the relay control signal corresponding to one or a plurality of load systems is switched from the commercial power supply designation state to the auxiliary power supply designation state when the preset time zone is reached.

  Which relay control signal is to be transmitted to each relay 12 is determined by a switching instruction signal from the main control board 14. The main control board 14 updates the switching instruction signal and transmits it to the relay control board 13 every time a load system that requires a change in power supply destination occurs. Each time the relay control board 13 receives a switching instruction signal, it determines a load system whose power supply destination is to be changed according to the latest switching instruction signal, and switches the state of the relay control signal for that load system.

A current sensor 15 (CT) is provided in a supply line of auxiliary power to the main breaker 10. Measurement data (indicating current value) by the current sensor 15 is transmitted to the main control board 14 via the relay control board 13.
The main control board 14 and the relay control board 13 include signal lines for transmission of measurement data (two lines), signal lines for power supply (three lines), and signal lines for transmission of control data (two lines). 2).

FIG. 4 is a block diagram showing a schematic configuration of the main control board 14 together with a relationship with peripheral configurations.
As shown in FIG. 4, the main control board 14 includes noise filters 101 and 102, a power switching electromagnetic relay 103, a power failure detection circuit 104, an AC / DC converter 105, and a DC for commercial power and auxiliary power, respectively. DC / DC converters 106 and 107, a communication circuit 108, a measurement processing unit 109, an arithmetic control unit 110, and the like are provided. The arithmetic control unit 110 is a microcomputer, and the measurement processing unit 109 is an IC chip dedicated to the processing. The communication circuit 108 is a circuit for wireless communication, and communicates with an external console 111 (in this embodiment, a tablet terminal device having a wireless function is used).

The commercial power supply and the auxiliary power supply are both 100V AC power supplies, and either one of the power supplies is selected by the electromagnetic switching relay 103 and connected to the subsequent stage.
The alternating current that has passed through the power switching relay 103 is converted into 12V direct current by the AC / DC converter 105, then converted into 5V direct current by the DC / DC converter 106, and further converted by the DC / DC converter 107 to 3V. Converted to 3V DC. The arithmetic control unit 110 operates by receiving a power supply of 3.3V DC, and the communication circuit 108 operates by receiving a power supply of 5V DC. The measurement processing unit 109 is supplied with both 3.3V direct current and 5V direct current.

  The relay control board 13 receives 3.3V direct current from one of the three power supply lines (see FIG. 2) to the main control board 14 and 12V direct current from the other one. The ground potential is transmitted by the remaining one. The relay control board 13 is also provided with a calculation control unit (not shown) by a microcomputer, and operates by receiving a power supply of 3.3 V direct current from the main control board 14. 12V direct current is supplied from the relay control board 13 to each relay 12 as a drive source of the relay 12.

  The power failure detection circuit 104 includes a rectifier circuit using a diode bridge, a smoothing circuit, a photocoupler, and the like (all not shown). The rectifier circuit and the smoothing circuit convert the commercial power supply through the noise filter 101 into a DC signal, and the signal is transmitted by the photocoupler.

The output terminal of the photocoupler is connected to the drive circuit of the arithmetic control unit 110 and the power supply switching relay 103. The arithmetic control unit 110 executes control described later while monitoring a signal from the photocoupler as a power failure detection signal.
Although not shown in FIG. 4, the drive circuit of the power switching relay 103 does not pass a current through the coil of the relay 103 while the output from the photocoupler continues, and the output from the photocoupler stops. It is designed to allow current to flow through the coil when supplied with auxiliary power. Further, when the coil is excited by this auxiliary power supply, the power supply line from the auxiliary power supply is connected to the subsequent circuit, and when the coil is demagnetized, the power supply line from the commercial power supply is connected to the subsequent circuit.

  Therefore, while the commercial power supply from the general distribution board 2 is supplied to the main control board 14 and the output from the photocoupler continues, the commercial power supply becomes a driving power supply for the power supply control device 1. On the other hand, when the commercial power supply fails and the output from the photocoupler is interrupted, the drive power supply is switched to the auxiliary power supply. In addition, the inversion of the power failure detection signal informs the arithmetic control unit 110 that the commercial power supply has failed.

  The auxiliary power supply line is branched before the noise filter 102, and the branch line is connected to the measurement processing unit 109. The measurement processing unit 109 includes a circuit that detects an AC voltage flowing through the branch line. Further, the measurement processing unit 109 inputs current measurement data transmitted from the current sensor 15 via the relay control board 13, and uses the current value indicated by the input data and the voltage value detected by the own circuit. The power supply amount (unit of power) per unit time is calculated. The result of this calculation is transmitted to the calculation control unit 110.

  The arithmetic control unit 110 receives a function that communicates with the console 111 via the communication circuit 108 by a program incorporated in the internal memory, and receives information set by an operation on the console 111 through the communication, and registers the information in the memory. Function, a function for generating a switching instruction signal to the relay control board 13 based on the registered information, a function for performing a statistical calculation using a calculation result from the measurement processing unit 109, and the power supply status to the console 111 based on the calculation result The function etc. which display the screen (refer FIG. 7) which shows etc. are set.

FIG. 5 shows an example of a setting screen displayed on the console 111.
On this screen, the name of the load system connected to each relay 12 is displayed together with a star mark M. The mark M can be switched between a brightly colored state and a contour-only state by a touch operation (in FIG. 5, the bright color is replaced with a halftone dot pattern). The load system corresponding to the brightly colored mark M is the priority load system.

  Although all load systems are set as priority load systems on the screen in the initial state, the number of priority load systems can be narrowed down by the user touching the mark M. Further, by touching the mark M of the load system that is out of the priority load system, the load system can be set as the priority load system again.

  Further, on this screen, a correction button 112 is provided for each load system. When the correction button 112 is touched, the screen is changed to a load system setting screen (not shown) corresponding to the button. In this dedicated setting screen, in addition to accepting changes to the name of the load system, schedule information (specifying the time zone for supplying power from the auxiliary power supply, etc.) when supplying auxiliary power to the corresponding load system in the event of a power failure Can be set.

Information set by the console 111 is transmitted from the communication circuit 108 to the arithmetic control unit 110 and registered in the memory in the arithmetic control unit 110. In the arithmetic control unit 110 of this embodiment, management information is associated with each load system identification number and registered in the memory, and flag data indicating whether or not the load system is a priority load system is stored in this management information. It includes flag data indicating whether or not auxiliary power is supplied in the event of a power failure, a time zone for the supply, and the like.
The management information associated with the load system identification number includes the identification numbers of the relay 12 and the auxiliary power supply side breaker 11. Similarly, the relationship between the identification numbers is also registered in the memory on the relay control board 13 side, and is used for controlling each relay 12.

  Based on the registered management information, the arithmetic control unit 110 sets a flag signal indicating whether the system is connected to a commercial power supply or an auxiliary power supply for each load system, and switches several bit configurations including each flag signal. An instruction signal is generated. The arrangement of the flag signals in the switching instruction signal is fixed in a certain order based on the identification number of the corresponding load system. This switching instruction signal is updated to the content suitable for the change whenever the change of the control content occurs, and is transmitted to the relay control board 13.

The arithmetic control unit of the relay control board 13 takes in the above switching instruction signal and sets a relay control signal for each relay 12 according to each flag signal in the signal.
According to FIG. 3, two signal lines for transmission of control data are provided between the main control board 14 and the relay control board 13, but the switching instruction signal is a serial signal of these signals. A signal transmitted from one of the lines and a response signal from the relay control board 13 to the main control board 14 in response to the switching instruction signal via the other signal line (notifying that each relay 12 has transmitted a relay control signal according to the switching instruction signal) To be sent).

FIG. 6 is a procedure of processing executed by the arithmetic control unit 110 for power supply control, and is divided into FIG. 6-1 showing a normal processing procedure and FIG. 6-2 showing a processing procedure during a power failure. . Hereinafter, the control in the arithmetic control unit 110 will be described in association with the operation of the relay control board 13 along the flow of these drawings.
In FIG. 6, the flag signal in a state instructing connection to the auxiliary power supply is turned on, and the flag signal in a state instructing connection to the commercial power supply is turned off. Further, the power failure detection signal when the commercial power is being supplied is turned off, and the power failure detection signal when the commercial power is interrupted is turned on.

  While the commercial power supply is being supplied, the commercial power supply is selected as the driving power supply, and the DC power derived from this power supply is supplied to various places. Under this state, the “normal process” procedure of FIG. 6A is executed. When the commercial power source fails, the auxiliary power source becomes the driving power source, and the processing of the arithmetic control unit 110 is switched to “power failure processing” of FIG.

First, the normal process will be described.
After being activated in response to the first power-on, the arithmetic control unit 110 turns off flag signals for all the load systems, and transmits a switching instruction signal including each flag signal to the relay control board 13 (step S _A 1 ).
In response to this transmission, the relay control board 13 sets the relay control signals for all the relays 12 to the commercial power supply designation state in accordance with each flag signal. With this setting, all the load systems connected to each relay 12 are connected to the commercial power source side breaker 21 and are supplied with commercial power.

Hereinafter, the operation control unit 110 monitors the change in the power failure detection signal (step S _A 2), pays attention to each load system in order, and stores the schedule information registered in the memory for the load system under consideration. It collates with the time measured by the timer (steps S _A 3 to S _A 8).

If it is determined by this verification that power supply from a commercial power source is being supplied to the load system under consideration but it is time to switch to power supply from an auxiliary power source (step S _A4 is “YES”), The arithmetic control unit 110 changes the flag signal for the load system under consideration from the OFF state to the ON state, and transmits a switching instruction signal including the changed flag signal to the relay control board 13 (step S _A 6). . When the load system under consideration is supplied with power from the auxiliary power supply, but when it is determined that it is time to end the power supply (step S _A5 is “YES”), the arithmetic control unit 110 Changes the flag signal for the load system under consideration from the ON state to the OFF state, and transmits a switching signal including the changed flag signal to the relay control board 13 (step S _A 7). In any of steps S _A 6 and S _A 7, the flag signals other than the flag signal of the load system under consideration in the switching instruction signal are maintained as they were immediately before.

When the load system under consideration has not reached the timing for starting the power supply from the auxiliary power supply or the time for ending the power supply (both steps S _A 4 and S _A 5 are “NO”), the flag signal is not changed. The switching instruction signal is not transmitted without being performed.
When the processing for each load system is completed (step S _A 8 is “YES”), the process returns to step S _A 2 and the same procedure as described above is repeated.

In the relay control board 13 that has received the switching instruction signal including the flag signal changed from the off state to the on state by the process of step S _A 6, the relay to the relay 12 connected to the load system for the changed flag signal is performed. The control signal is switched from the commercial power supply designation state to the auxiliary power supply designation state. The relay control signals to the other relays 12 are continuously maintained in the commercial power supply designation state. By this control, only the load system set as the power supply target is connected to the auxiliary power supply side breaker 11 and supplied with auxiliary power, and the other load systems continue to receive commercial power.

In the relay control board 13 that has received the switching instruction signal including the flag signal changed from the on state to the off state by the process of step S _A 7, the relay to the relay 12 connected to the load system for the changed flag signal is performed. Return the control signal to the commercial power supply designation state. By this setting change, the connection destination of the load system connected to the auxiliary power supply side breaker 11 is switched to the commercial power supply side breaker 21, and commercial power is again supplied.

Incidentally, the same if the load system supplied with auxiliary power there are multiple time zone, in step S _A. 3 to switching instruction signal in step S _{A 6} in the loop of steps S _{A 8} when entered the time slot Transmission is executed a plurality of times, and the corresponding relay 12 is sequentially switched to the auxiliary power supply side breaker 11 under the control of the relay control board 14 that receives the transmission. Similarly, when there are a plurality of load systems in which the supply of auxiliary power ends in the same time zone, the switching instruction by step S _A 7 in the loop of step S _A 3 to step S _A 8 when entering the time zone is similarly performed. The transmission of the signal is executed a plurality of times, and the corresponding relay 12 is sequentially switched to the commercial power supply side breaker 21 under the control of the relay control board 14 that receives the signal transmission.

When the commercial power supply fails, the power failure detection signal changes from the off state to the on state (step S _A2 is “YES”). The arithmetic control unit 110 that has detected this change interrupts the normal processing and shifts to the power failure processing.

Switching the reference to FIG. 6-2, the power failure process will be described. In the power failure process, based on the priority load system registration information, the flag signal for the priority load system is turned on, and the other flag signals are turned off. Then, a switching instruction signal including each flag signal is transmitted to the relay control board 13 (step S _B 1).

  In the relay control board 13 that has received the transmission of the switching instruction signal, the relay control signal to the load system relay 12 for the flag signal in the on state is set to the auxiliary power supply designation state, and the relay control to the other relays 12 is performed. Set the signal to the commercial power supply specified state. With this setting, only the priority load system can be connected to the auxiliary power supply side breaker 11 to supply auxiliary power.

Further, after the power failure, when the user performs an operation of changing the selection state of the priority load system using the console 111, step S _B 2 becomes “YES” after step S _B 1 is executed, and step S _B 1 Return to. As a result, the flag signal for each load system is updated according to the changing operation and transmitted to the relay control board 13. The relay control board 13 that has received this transmission also changes the relay control signal to each relay 12 to a state corresponding to the updated flag signal.

When the commercial power supply is restored and the power failure detection signal returns from the on state to the off state (step S _B3 is “YES”), the arithmetic control unit 110 ends the power failure process, and from the normal time process step S _A 2 Resume normal processing.

The switching instruction signal also includes a flag signal for the switch 30 between the auxiliary power supply 3 and the outlet 5B. Further, the schedule information registered in the arithmetic control unit 110 includes a time zone in which the auxiliary power supply device 3 is charged.
Although not shown in the flowchart, the arithmetic processing unit 110 also checks whether or not the time for charging the auxiliary power supply device 3 has been entered in the normal processing. If it is determined that the charging time zone has been entered, all flag signals including the flag signal for the switch 30 are turned off, and a switching instruction signal is transmitted. In response to this transmission, the relay control board 13 switches the relay control signal for the switch 30 so that the auxiliary power supply 3 and the outlet 5B are connected, and relay control signals for all the relays 12 are used for commercial use. Set to the power supply specified state.

When the time period for charging the auxiliary power supply 3 ends, the arithmetic control unit 110 changes the flag signal for the switch 30 from the on state to the off state, and includes a switch instruction signal ( Other flag signals are not changed.)
In the relay control board 13 that has received this transmission, the relay control signal for the switch 30 is switched to disconnect the power supply path to the auxiliary power supply device 3.

  As described above, when the commercial power supply fails, regardless of the previous power supply state, only the predetermined priority load system is connected to the auxiliary power supply and supplied with the auxiliary power supply. A power failure occurs. In this way, when the commercial power supply fails, auxiliary power can be supplied only to important load systems. Further, even during normal times when commercial power is not stopped, auxiliary power can be periodically supplied to one to a plurality of load systems according to schedule information.

  Setting of the priority load system, the load system to which the auxiliary power supply is normally supplied, and the power supply time zone can be freely set using the console 111. Similarly, the setting can be easily changed using the console 111. Therefore, depending on the load system that the user needs to operate in an emergency, the charging capacity of the auxiliary power supply 3, etc., the load system of the power supply destination can be variously set, and when inconvenience occurs, You can also change that setting. In addition, since the priority load system can be changed even when the commercial power supply is interrupted, auxiliary power can be supplied to the load system that was not intended in advance but must be moved due to a power outage. Even when it is desired to cancel the power supply from the auxiliary power supply to some of the priority load systems in order to save power, it can be easily handled.

  In the above-described embodiment, the switching instruction signal transmitted from the main control board 14 to the relay control board 13 is a signal having a multi-bit configuration in which a flag signal for each load system is connected. Each time a change occurs, a switching instruction signal reflecting the change is generated by the main control board 14 and transmitted to the relay control board 13. However, the transmission form of the switching instruction signal and the control procedure are limited to this. It is not something.

  For example, in the main control board 14, the state of the power failure detection signal is checked at regular time intervals, and if the power failure detection signal is in an off state (a state in which commercial power is supplied) Based on the schedule information, the state of the flag signal (on state during power feeding period, off state during power feeding period) is set, and a switching instruction signal based on these settings is transmitted. On the other hand, if the power failure detection signal is in the on state (commercial power is in a power failure state), the flag signal for the load system set as the priority load system is turned on, and the flag signals for the other load systems are turned off. A switching instruction signal is transmitted. When such processing is performed, a switching instruction signal is periodically transmitted to the relay control board 13. However, in the relay control board 13, the change of the flag signal in the hourly switching instruction signal is changed for each load system. What is necessary is just to switch the relay control signal with respect to the load system which detected and changed.

  The power supply line of the main control board 14 and the power supply line of the auxiliary power supply are insulated by the power supply switching relay 103, and the load between the power supply line of each commercial power supply line and the auxiliary power supply line is also loaded. Since it is insulated by the relay 12 corresponding to the system, there is no possibility that the current due to the power supply flows into the line on the commercial power source side when power is supplied from the auxiliary power supply. Therefore, reverse power flow to the commercial power supply side can be prevented, and power supply efficiency can be increased.

Further, in the management control device 1 of this embodiment, a screen as shown in FIG. 7 can be displayed on the console 111 by information processing by the arithmetic control unit 110.
This screen is displayed in response to a call operation on a menu screen (not shown). On the screen, the auxiliary power supply device 3 is expressed as “storage battery” for the user, and an image 121 and a numerical value display column 122 showing the current power storage rate, the current value of the power supply amount from the auxiliary power supply, and the cumulative value for today A display column 123, a graph 124 indicating a time-series change in the power supply amount, a column 125 indicating the current state of each load system, and the like are displayed. In addition, a button 120 with characters “SETTING” is provided on the screen. When this button 120 is touched, the screen is switched to the setting screen shown in FIG. The setting screen can also be called from the menu screen.

  The power supply amount shown in the column 123 and the graph 124 is obtained from the power measurement data input from the measurement processing unit 109. The storage rate in the column 122 is calculated from the charging capacity of the auxiliary power supply device 3, the power supply amount, the charge amount of the auxiliary power supply device 3, and the like. The amount of charge is determined, for example, by the time when the switch 30 is closed (specifically, the time when the flag signal for the switch 30 is set to ON) based on the log information in the memory of the arithmetic control unit 110 as the charge time. Can be calculated by a method of multiplying the amount of charge per unit time inputted in advance from the console 111.

In the display column 125 for the status of each load system, the registered name of each load system is displayed together with the characters “power supply” or “commercial”. “Power supply” means that the corresponding load system is currently connected to the auxiliary power supply, and “commercial” means that the corresponding load system is currently connected to the commercial power supply.
The indication of “power supply” and “commercial” is derived from the setting state of each flag signal in the latest switching instruction signal. That is, the word “power supply” is associated with the load system for the flag signal that is set to the on state by the latest switching instruction signal, and the load system for the flag signal that is set to the off state by the latest switching instruction signal. "Commercial" characters are associated.

  According to the above display, how much power is stored in the auxiliary power supply device 3, whether the user can afford to increase the load system supplying the auxiliary power, or should the number of auxiliary power supply destinations be reduced? Etc. can be easily determined. If it is determined that the setting needs to be changed, the setting screen can be called by the button 120 and the necessary setting change can be performed.

  In order to introduce the above power supply control device 1 into a power supply system in an existing house, the installer installs the power supply control device 1 at an appropriate place in the house, and the main breaker 20 of the general distribution board 2 or the commercial power source. One of the side breakers 21 is connected to the main control board 14, and the discharge side line of the auxiliary power supply device 3 is connected to the main control board 14 and the main breaker 10. Moreover, the load system which enables supply of an auxiliary power supply is determined, the connection line between these load systems and the commercial power source side breaker 21 is cut off, and one of the relays 12 in the power supply control device 1 is connected to both. To be connected through. Further, when the auxiliary power switch 30 is used, the switch 30 is connected to the relay control board 13 and the connection to the general distribution board 2 is not disconnected via the switch 30. The outlet 5B is connected to the charging side line of the auxiliary power supply device 3. When the switch 30 is not used, the charging side line of the auxiliary power supply device 3 is directly connected to the outlet 5B.

  When installation of the power supply control device 1 and electrical connection are completed and supply of commercial power to the main control board 14 is started, the contractor uses the console 111 to specify the name of the load system connected to each relay 12. Set. Moreover, although a priority load system and schedule information are set according to a user's request, the setting may be performed by the user himself / herself.

  Note that the tablet terminal used as the console 111 is not limited to one having a wireless function, and may be electrically connected to the arithmetic control unit 110 via a USB interface or the like. Instead of the terminal device, the operation panel may be fixed to the apparatus main body, or instead of the operation panel, a number of switches and display units corresponding to each load system may be provided. In addition, it is possible to provide only the switch without providing the display function, but in that case, the correspondence between the switch and the load system, such as sticking the name of the load system corresponding to each switch, is attached. It is necessary to devise so as not to make a mistake.

In the power supply control device 1 of the above embodiment, for the relay control board 13 that directly controls the operation of each relay 12, switching including instructions for all the relays from the main control board 14 whenever the control content needs to be changed. The method of transmitting the instruction signal is employed, but the control method is not limited to this. For example, as a flag signal for each load system and the switch 30 is transmitted through an individual signal line, a voltage level signal corresponding to the current setting state of the flag signal is constantly transmitted from the main control board 14, The relay control board 13 may detect the switching of the flag signal and switch the corresponding relay control signal.
Further, the main control board 14 and the relay control board 13 are integrated into one control board, and the operation of each relay 12 is controlled on the control board while detecting the power failure of the commercial power supply and switching the main power supply. Good.

In the above embodiment, each power supply line is a single-phase two-wire system. However, when a single-phase three-wire power supply line is used, a commercial power supply and an auxiliary power supply are connected for each load system using the same mechanism. Can be switched. In addition, the relay 12 used for this switching is not limited to the two-pole two-phase type described above, and other types can be used, and the signal line between the main control board 14 and the relay control board 13 can be used. The type and number can be changed as appropriate.
The commercial power supply and auxiliary power supply are not limited to 100V, and can support 200V AC.

  Next, in the above description, an example in which the power supply control device 1 is introduced into a power supply system that covers only power from a commercial power source has been described. However, the power supply control device 1 of the present invention has a private power generation system such as solar power generation. Can also be introduced. FIG. 8 shows an example of the introduction.

FIG. 8 shows a relationship between a primary system that supplies power using electric power generated by a commercial power source and solar power generation, and a secondary system that receives power from the primary system.
The primary system includes a power generation module 60 including a solar panel, a power conditioner 61, a power purchase meter 62, a power sale meter 63, and the like. The power conditioner 61 is connected to the same power supply line 65 as the commercial power source. A power purchase meter 62 and a power sale meter 63 are also interposed in the power supply line 65.
The secondary system has the same configuration as that of the example of FIG. 1 except that the feeder line 65 is connected to the main breaker 20 of the general distribution board 2.

  The power conditioner 61 converts the direct current power generated by the power generation module 60 into alternating current whose voltage and frequency match the commercial power source, and sends the alternating current to the power supply line 65. When the amount of power generated by solar power generation is zero (nighttime) or when the amount of power generation is less than the amount of demand on the secondary system side, insufficient power is taken in from the commercial power source. However, the power transmitted from the power supply line 65 via the general distribution board 2 is stored in the auxiliary power supply device 3, and the time zone for receiving power supply from the auxiliary power supply and the load system to be supplied with power are registered in the main control board 14. By doing so, it becomes possible to cover the power necessary for the secondary system at night or the like with an auxiliary power source.

On the other hand, when the amount of power generated by photovoltaic power generation exceeds the amount of power consumed in the secondary system, a reverse power flow occurs in which the surplus power flows to the commercial power source side.
The power purchase meter 62 measures the amount of power flowing from the commercial power source to the secondary system via the primary system, and the power selling meter 63 measures the amount of power in the reverse power flow. The measured values of the meters 62 and 63 are used for a settlement process at an electric power company.

FIG. 9 shows a conventional example of a power feeding system having a solar power generation function. In this example, the general distribution board 2 is the only secondary system. Although not shown in the figure, a load system is directly connected to each breaker 21 of the general distribution board 2.
In the primary system, the auxiliary power supply device 31 is provided and connected to the power conditioner 61, but the other configuration is the same as the example of FIG.

  The power conditioner 61 sends electric power generated by solar power generation to the power supply line 65. When the amount of power generated by this solar power generation exceeds the amount of demand on the secondary system side, a reverse power flow due to the surplus power occurs.

  The power conditioner 61 can charge the auxiliary power supply 31 with the electric power generated by the reverse power flow. When the amount of power generated by solar power generation is zero (nighttime) or when the amount of power generation is less than the amount of demand on the secondary system side, the shortage of power is taken in from the commercial power supply, but the auxiliary power supply 31 When the electric power is charged, the power conditioner 61 can discharge the auxiliary power supply device 31 and send the electric power generated by the discharge to the power supply line 65.

  However, in this conventional example, the auxiliary power supply device 31 is provided on the primary system side, and the charging line and the discharging line are connected to the same power supply line 65 via the power conditioner 61. In addition to the power generated by solar power generation, there is a possibility that the power taken in from the commercial power supply is charged to the auxiliary power supply 31. In addition, when the power generator 61 generates a power that can meet the demand on the secondary system side by photovoltaic power generation due to a malfunction of the power conditioner 61, the auxiliary power supply 31 is discharged. There is a possibility of reverse power flow due to surplus power. If so, the power provided from the commercial power source is included in the power provided to the electric power company as the power sold, and there is a possibility that the settlement based on the measured value by the power purchase meter or the power sale meter may be hindered.

  On the other hand, in the power supply system shown in FIG. 8, the auxiliary power supply device 3 is disposed on the secondary system side, and the charging side line and the discharging side line are connected to different paths. The main control board 14 is supplied with commercial power and auxiliary power. As shown in FIG. 4, the power supply lines of both power sources are insulated by the power switching relay 103. In addition, regarding the power supply to each load system, the power supply line from the auxiliary power supply side breaker 11 and the power supply line from the commercial power supply side breaker 21 connected to the primary system are insulated by the relay 12, so that the reverse power flow is completely eliminated. Is prevented.

  The auxiliary power supply 3 of the embodiment of FIG. 8 may be charged with power from commercial power in addition to power from solar power generation. As described above, the power supply line of the auxiliary power supply is completely connected from the primary system. Since it is insulated, the electric power generated by the discharge of the auxiliary power supply 3 is only used in the secondary system, and there is no possibility of flowing out to the power supply line on the primary system side. Therefore, the reliability of the measured value by the power purchase meter and the power sale meter is ensured, and the settlement process can be performed without any trouble.

DESCRIPTION OF SYMBOLS 1 Power supply control apparatus 2 General distribution board 3 Auxiliary power supply apparatus 11 Auxiliary power supply side breaker 12 Electromagnetic relay 13 Relay control board 14 Main control board 21 Commercial power supply side breaker 103 Power supply switching relay 104 Power failure detection circuit 108 Communication circuit 110 Operation control section 111 console

Claims (2)

A device for controlling power supply to a plurality of load systems from a general distribution board receiving power supply from a commercial power source and an auxiliary power device having a charging function from the commercial power source and the photovoltaic power generation module ,
A plurality of breakers connected to the auxiliary power supply line by the auxiliary power device, a number of switching units corresponding to these breakers, a control unit for individually controlling the operation of each switching unit, and the contents of the control And an operation unit for setting,
Each switching unit is configured to connect one of the plurality of breakers and one of the plurality of breakers in the general distribution board to a predetermined load system, which is designated by the control unit. And
The controller is
A control circuit including a memory in which information for identifying a switching unit corresponding to a priority load system to be preferentially supplied with auxiliary power in the event of a power failure of the commercial power source is registered;
A conversion circuit that converts 100V AC supplied from a commercial power supply or an auxiliary power supply device into a DC voltage having a magnitude for driving the control circuit, and supplies the DC voltage to the control circuit;
A power failure detection circuit for detecting a commercial power failure from the general distribution board;
Connected to the commercial power supply, the auxiliary power supply device, and the power failure detection circuit , the commercial power supply is connected to the conversion circuit during an off state in which a detection signal from the power failure detection circuit does not indicate a power failure of the commercial power supply, A power switching circuit that switches a power source connected to the conversion circuit from a commercial power source to an auxiliary power source when the detection signal is switched from an off state to an on state indicating a power failure of the commercial power source,
The control circuit includes:
A detection signal from the power failure detection circuit is input, and the detection signal is changed from the off state to the on state, and based on information registered in the memory, the switching unit for the priority load system includes the A switching control means for designating that the breaker on the auxiliary power supply side is connected to the priority load system, and that the switching unit for the other load system is designated to connect the breaker in the general distribution board to the load system; ,
Registration for updating information for identifying a switching unit corresponding to the priority load system registered in the memory, based on the designated content when an operation for designating a priority load system is performed in the operation unit A power supply control device comprising: an information updating unit. The operation unit is capable of accepting an operation for designating a time zone for supplying power from the auxiliary power supply device for each load system under a state where the commercial power supply is not interrupted,
In the control circuit, according to the operation described above, schedule information in which a switching unit connected to a load system designated to perform power feeding from the auxiliary power supply device and a designated time zone for the power feeding are associated with each other Is further provided with a schedule registration means for registering in the memory, and a timer for measuring time,
While the detection signal from the power failure detection circuit is maintained in the off state, the switching control means is based on the timer timing and schedule information in the memory for each designated time zone for power supply. While specifying that the auxiliary power source side breaker is connected to the load system to the switching unit for the load system for which the time zone is specified, the switching unit for the other load system is connected to the breaker in the general distribution board. The power supply control device according to claim 1, wherein the power supply control device designates connection to a load system.

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