JP2014027710A - Power supply control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique for suppressing electrical energy consumed by a Hall element when measuring a current flowing through a distribution board/devices by means of the Hall element.SOLUTION: A current sensor 6 is connected to a central monitoring device 13 via a bus cable 14. The central monitoring device 13 includes a measured current information management section 13a for managing measured current information acquired from the current sensor 6, and a power supply control section 13b for controllingly supplying power to the current sensor 6 only during current measurement.

Description

  The present invention relates to a system for controlling power supply to a current sensor that detects a current value flowing in an electric device in an electric storage box such as a distribution board, a distribution board, or a control board.

  As a method of measuring the current flowing through the distribution board / equipment, a method using a current transformer (coil type) (for example, Patent Document 1), a method using a shunt resistor (shunt), or a method using a Hall element ( For example, any one of Patent Document 2) is generally adopted.

  The method using a current transformer (coil type) has a drawback in that it cannot be measured in principle, and therefore lacks versatility, for example, it cannot measure the DC component of a battery. In addition, it is ideal to reduce the size in consideration of workability, but in the case of a current transformer, if it is attempted to reduce the size, the number of windings of the coil formed inside the current transformer cannot be secured. It was very difficult to make it.

  The method using a shunt resistor (a shunt resistor) can measure both AC and DC, but has a drawback that electrical insulation is not easy. In addition, when a large current of several hundreds of A flows, the heat generation is large and the size is large, which is not suitable for downsizing.

  The method using a Hall element (hereinafter referred to as a magnetic detection element) detects a magnetic field generated by an electric current. On the substrate constituting the current measuring means (hereinafter referred to as current sensor) used in this method, there is an integrated circuit for detecting the output data of the magnetic detection element and calculating the current value in addition to the magnetic detection element for detecting the magnetic field. It is installed. This current sensor can measure both AC and DC, and can have a compact device configuration. However, this method using a current sensor can overcome the drawbacks of the above-mentioned methods. However, in order to amplify the output data of the magnetic detection element with an integrated circuit, it is necessary to supply power from an external power source. When the current measurement means is arranged at a plurality of locations and current measurement is performed, the amount of power consumed by the current measurement means increases, which is not preferable from the viewpoint of energy saving.

JP 2008-289301 A Noto 3142092

  The object of the present invention is to solve the above-mentioned conventional problems, and when measuring the current flowing in the electrical equipment in the electrical storage box such as the distribution board, switchboard, control panel, etc. using the magnetic detection element, It is to provide a power supply control system capable of suppressing the amount of power consumed by a current sensor.

  The power supply control system of the present invention made to solve the above problems controls power supply to a current sensor that measures a current flowing to each electric device in an electric device storage box containing a plurality of electric devices. A power supply control system, wherein the current sensor is connected to a central monitoring device via a bus cable, and the central monitoring device includes a measurement current information management unit that manages measurement current information acquired from the current sensor; A power supply control unit that controls the power supply to the current sensor to be performed only at the time of current measurement is provided.

  According to a second aspect of the present invention, in the power supply control system according to the first aspect, the electric device storage box includes a plurality of current sensors, and the power supply control unit sequentially switches the power supply to the plurality of current sensors. It is characterized by controlling so that it may be performed.

  According to a third aspect of the present invention, in the power supply control system according to the second aspect, the measurement current information management unit detects the number of current sensors used in the electrical equipment storage box, and measures a plurality of current sensors. The cycle time is controlled.

  According to a fourth aspect of the present invention, in the power supply control system according to the first aspect, the pair of arms protrudes from one end of the substrate and the inside thereof is used as a wiring insertion portion having an open end, and the pair of arms The magnetic detection element is arranged in each of the sections, and is arranged in an electric circuit inside each electric device or an electric circuit that supplies power to the electric device.

  In the present invention, a current sensor is connected to a central monitoring device via a bus cable, and the central monitoring device includes a measurement current information management unit that manages measurement current information acquired from the current sensor, and a current sensor. By adopting a configuration including a power supply control unit that controls so that power supply is performed only at the time of current measurement, compared to the conventional case where power supply is always performed for a current sensor equipped with a magnetic detection element, The amount of power consumed by the sensor can be suppressed.

  Even when a plurality of current sensors are provided in the electrical equipment storage box by controlling so that power supply to the plurality of current sensors is sequentially switched as in the invention described in claim 2, The power consumption in the sensor can be suppressed.

  As in the third aspect of the invention, the measurement current information management unit detects the number of current sensors used in the electric equipment storage box, and controls the measurement cycle time for the plurality of current sensors, thereby providing a circuit. Even when the number is changed, it is possible to keep a certain measurement time.

  According to a fourth aspect of the present invention, a pair of arm portions are projected from one end of the substrate and the inside thereof is used as a wire insertion portion with the end portions open, and a magnetic detection element is disposed on each of the pair of arm portions. By using a current sensor that is arranged in the electric circuit inside each electric device or an electric circuit that supplies power to the electric device, the space for arranging the current sensor is greatly reduced, and various wirings are provided in the electric device. Even in the completed state, it is possible to easily perform the assembly work.

It is explanatory drawing of embodiment which has arrange | positioned the current sensor in the branch breaker. It is explanatory drawing of embodiment which has arrange | positioned the current sensor to the electrical circuit which supplies power to a branch breaker from a bus-bar. It is a figure explaining a power supply control system. It is a figure explaining a power supply control system. It is a figure explaining a power supply control system. It is a figure explaining a power supply control system. It is a perspective view of a current sensor and a case. It is explanatory drawing (front sectional drawing) of the current sensor attachment structure of a branch breaker. It is explanatory drawing (perspective view) of the current sensor attachment structure of a branch breaker. It is a figure which shows the flowchart of a power supply control system.

  Preferred embodiments of the present invention are shown below.

  The power supply control system according to the present invention supplies power to a current sensor that measures the current flowing to each electrical device in an electrical device storage box containing a plurality of electrical devices such as distribution boards, switchboards, and control panels. It is something to control. Note that the current sensor used in the present embodiment uses a current sensor that requires power supply using a magnetic detection element or the like. In the present embodiment, as shown in FIGS. 1 and 8, an example is shown in which current sensors are arranged inside a plurality of branch breakers 2 constituting the distribution board 1.

  As shown in FIGS. 8 and 9, the current sensor 11 used in the present embodiment is arranged so that the current sensor 11 straddles the electric circuit 18 inside the branch breaker 2, but the arrangement position of the current sensor 6 is There is no particular limitation as long as it is on the electric path for supplying power to the electrical equipment. For example, as shown in FIG. 2, three bus bars 5 connected to the secondary side of the main breaker 3 via lead bars 4. The current sensor 6 can also be arranged on the branch lead bar 19 which is an electric circuit for supplying power to the branch breaker 2. Further, in the present embodiment, the current sensor 6 is disposed on the distribution board, but may be disposed on an electrical device other than the distribution board.

  As described above, the current sensor 6 needs to be supplied with power from an external power source. In the present invention, as shown in FIGS. A monitoring device 13 is provided, the central monitoring device 13 and the current sensor 6 are connected via a bus cable 14 incorporating a power supply line and a signal line, and power is supplied via the power supply line. Note that the power line can be arranged as an independent power supply line instead of in the bus cable 14, or the power of the current sensor 6 can be obtained from the electric path 18 to which the current sensor 6 is connected. It may be formed outside.

  The bus cable 14 is formed with a connection connector 15 used for connection to the current sensor 6. The arrangement | positioning location of the central monitoring apparatus 13 is not specifically limited, In this embodiment, you may arrange | position either inside or outside a distribution board.

  Transmission of power supply control information and operation control of the current sensor 6 are performed between the central monitoring device 13 and the current sensor 6 via a signal line built in the bus cable 14.

  The central monitoring device 13 includes a measurement current information management unit 13a that manages measurement current information acquired from the current sensor 6, and a power supply control unit 13b that controls so that power supply to the current sensor is performed only during current measurement. Yes. As described above, by providing the power supply control unit 13b for controlling the power supply to the current sensor 6 to be performed only at the time of the current measurement, compared to the case where the power supply to the current sensor 6 has been constantly performed. Power consumption can be suppressed. The data stored in the central monitoring device 13 is used for checking information managed by the measured current upper management unit 13a from an external monitoring PC, moving it through a memory card, etc. A box can be provided with a monitor.

  In this embodiment, as shown in FIGS. 3 to 6, each of the branch breakers 2 constituting the distribution board 1 is provided with a current sensor 6, and power is supplied to the plurality of current sensors 6 simultaneously. In order not to be interrupted, control is performed to sequentially switch the current sensors 6 to be supplied with power.

  Specifically, first, as shown in FIG. 3, the power supply control unit 13b of the central monitoring device 13 sends an ON command to start power supply to one current sensor 6 to close the power supply circuit. An electric circuit is formed and power supply is started. Subsequently, as shown in FIG. 4, the result measured by the current sensor 6 is recorded in the measured current information management unit 13 a of the central monitoring device 13. After that, as shown in FIG. 5, the power supply control unit 13b of the central monitoring device 13 sends an OFF command for stopping power supply to the current sensor 6 that is supplying power, opens the power supply circuit and stops power supply. To do. After the end of the above cycle, as shown in FIG. 6, power is supplied to the current sensor 6 different from the current sensor 6 to which power has been supplied in the same process as described above. As described above, even when power is supplied to the plurality of current sensors 6, power is supplied to the plurality of current sensors 6 at the same time by performing control so that the supply destinations (current sensors 6) are sequentially switched. The maximum power consumption per unit time can be suppressed. A flow chart at the time of the measurement shown above is shown in FIG. First, a current flows when the central monitoring device 13 issues an ON command to the device (1). Next, a current flows through the current sensor 6 when the current sensor 6 of the device (1) is turned on. It is possible to suppress the current value by turning off the central monitoring device 13 during the measurement of the current sensor 6. Next, after the current sensor 6 of the device (1) measures the current value, the central monitoring device 13 is turned on in order to receive the measured current value from the current sensor 6. Thereafter, an OFF signal is sent from the central monitoring device 13 to the device (1), and the current sensor 6 of the device (1) is turned off. Finally, after the measured current value is stored in the measured current information management unit 13a, the central monitoring device 13 is turned off. The maximum power per unit time can also be suppressed by performing control so that the cycles are sequentially switched. If the central monitoring device 13 detects that the power supply of the current sensor 6 is stopped or the current sensor 6 is OFF, the control is performed so that the next process is performed. Even when a single current sensor 6 is formed, it is possible to suppress the maximum power consumption because the operating current sensor 6 is always controlled to be only one.

  Further, the number of current sensors 6 formed in the plurality of branch breakers 2 constituting the distribution board 1 is detected by the power supply control unit 13b of the central monitoring device 13. Then, the measurement cycle time of the plurality of current sensors 6 is controlled according to the detected number of current sensors 6. If control is possible in this way, a constant measurement time can be maintained even when the number of circuits is changed. If it is also possible to set the 6 measurement times of all current sensors, the ON / OFF cycle can be lengthened even when the number of current sensors increases. It is possible to reduce the applied load.

  Here, the current sensor 6 desirably used in the present embodiment will be described. As shown in FIG. 7, the current sensor 6 has a substantially U-shaped structure in which one end of the substrate 7 is opened to form a pair of arm portions 8, and a magnetic detection element 9 is mounted on the pair of arm portions 8. doing. Further, a portion formed by opening one end of the substrate 7 is a wiring insertion portion 8a through which the electric circuit 18 is inserted.

  As shown in FIG. 8, the magnetic detection element 9 mounted on the current sensor 6 detects a magnetic field generated by a current flowing in the electric path 18 disposed in the wiring insertion portion 8 a between the arm portions 7. In addition, an integrated circuit 10 for processing the detection output of these magnetic detection elements 9 and calculating the value of the current flowing in the electric circuit 18 is also mounted. In the present embodiment, one magnetic detection element 9 is mounted on each arm portion 7, but a plurality of magnetic detection elements 9 may be mounted. By mounting a plurality, it is possible to investigate the current flowing through the electric circuit 18 more accurately.

  As described above, by using the substrate-shaped current sensor 6, it is possible to greatly reduce the arrangement space of the current sensor as compared with the case where the conventional core-shaped current sensor is used. In addition, in the conventional core-shaped current sensor, when installing the current sensor, it is necessary to pass wiring through the core-shaped current sensor. When CT is installed after the distribution board is installed, all branch breakers must be installed. However, the current sensor 6 used in the present invention has one end of the substrate 7 opened, which requires a troublesome work for assembling work. Therefore, even when various wirings are made after the distribution board is installed, the assembling work can be easily performed.

  In the present embodiment, as shown in FIG. 9, the current sensor 6 is inserted into the current sensor insertion portion 17 formed in the branch breaker 2 with the case 11 covering the entire current sensor 6. The current sensor insertion portion 17 is formed to have substantially the same width as the case 11 in order to prevent rattling of the inserted case 11.

  As shown in FIG. 7, the case 11 is formed in a substantially U-shaped structure having a pair of arm portions 12, similar to the current sensor 6. A connection connector mounting portion 16 through which the connection connector 15 is detachably inserted is formed on the upper portion of the case 11. When the connection connector 15 is not inserted, the connection connector mounting portion 16 is preferably prevented by a blank panel, a seal, or the like to prevent entry of dust or the like. In addition, when the connection connector 15 is inserted through the connection connector mounting portion 16, the board 7 of the current sensor 6 receives the pins of the connection connector 15 so that the connection connector 15 and the current sensor 6 are connected ( (Not shown) is formed. By connecting the connection connector 15 and the current sensor 6, a control signal from the central monitoring device 13 is transmitted to the current sensor 6, and the power supply control described above is performed. Further, as shown in FIG. 9, a connecting connector insertion portion 20 is formed in the direction of the bus bar 5 of the branch breaker 2, and when the connecting connector 15 is inserted, it is connected to the connecting connector mounting portion 16 of the case 11. It is formed so that. In addition, when the current sensor 6 is not used also in the connection connector insertion part 20, it is closed with a blank panel or a seal.

  If the positional relationship between the electric path 18 and the magnetic detection element 8 is deviated, the current detection error is affected. Therefore, it is preferable that the current sensor 6 be arranged so as not to cause backlash. Specifically, a guide inclined portion is formed at the entrance where the electric path 18 is inserted so that the electric path 18 is inserted into a desired fixed position (near the center line of the current sensor 6) with respect to the current sensor 6. Is preferred. Further, it is desirable to provide a metal electric circuit mounting portion (not shown) between the arm portions 12 of the case 11 so that the electric circuit can be elastically inserted.

DESCRIPTION OF SYMBOLS 1 Distribution board 2 Branch breaker 3 Main breaker 4 Lead bar 5 Bus bar 6 Current sensor 7 Board | substrate 8 Arm part 8a Wire insertion part 9 Magnetic detection element 10 Integrated circuit 11 Case 12 Arm part 13 Central monitoring apparatus 13a Measurement current information management part 13b Power supply control unit 14 Bus cable 15 Connection connector 16 Connection connector mounting portion 17 Current sensor insertion portion 18 Electric path 19 Branch lead bar 20 Connection connector insertion portion

Claims (4)

In an electrical equipment storage box containing multiple electrical equipment,
A power supply control system that controls power supply to a current sensor that measures a current flowing to each electrical device,
The current sensor is connected to the central monitoring device via the bus cable,
The central monitoring device includes a measurement current information management unit that manages measurement current information acquired from the current sensor, and a power supply control unit that controls power supply to the current sensor only during current measurement. A featured power supply control system. Equipped with multiple current sensors in the electrical equipment storage box,
The power supply control system according to claim 1, wherein the power supply control unit performs control so that power supply to the plurality of current sensors is sequentially switched.   3. The power supply control system according to claim 2, wherein the measurement current information management unit detects the number of current sensors used in the electric equipment storage box and controls the measurement cycle time for the plurality of current sensors. .   The current sensor has a structure in which a pair of arm portions are projected from one end of a substrate and the inside thereof is a wiring insertion portion having an open end portion, and a magnetic detection element is disposed in each of the pair of arm portions. The power supply control system according to claim 1, wherein the power supply control system is disposed in an electric circuit inside the device or an electric circuit that supplies power to the electric device.