JP2009261087A - Current distribution apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To avoid shut down of a normal communication device when short circuit fault occurs. <P>SOLUTION: A current distribution apparatus 1 includes interrupting sections 11-1 and 11-2 connected, respectively, with communication devices 3-1 and 3-2 and interrupting supply of DC currents distributed to the communication devices 3-1 and 3-2 based on the values of DC currents from a distributed rectifying apparatus 2. Furthermore, the current distribution apparatus 1 includes a capacitor 12 having one end connected with the interrupting sections 11-1 and 11-2 by wiring shorter than the wiring from the rectifying apparatus 2 to the interrupting sections 11-1 and 11-2 and the other grounded end, and a large-capacity capacitor 13 with a storage capacity larger than that of the capacitor 12 connected in parallel with the capacitor 12 and having one end connected with the interrupting sections 11-1 and 11-2 by wiring shorter than the wiring from the rectifying apparatus 2 to the interrupting sections 11-1 and 11-2. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a current distribution device.

  Generally, a current distribution device that distributes a DC current between a current supply device and a plurality of load devices in order to supply a DC current output from a current supply device such as a rectifier to a plurality of load devices. Is considered a current distribution system.

  For example, a general current distribution system having a configuration shown in FIG. 6 is considered (for example, see Non-Patent Document 1).

  In this current distribution system, the rectification unit 210 included in the rectifier 200 generates a direct current by rectification of an alternating current input from the commercial power supply 400 and outputs the generated direct current to the current distributor 100.

  The current distribution device 100 branches the direct current output from the rectifying device 200 into two systems. The branched direct currents are supplied to communication modules 310-1 and 310-2 included in communication devices 300-1 and 300-2 via fuses 110-1 and 110-2, respectively. Each branched direct current charges capacitors 320-1 and 320-2 provided on the input sides of communication devices 300-1 and 300-2, respectively. Capacitor 320-1 or 320-2 matches the external impedance connected to the input side of communication device 300-1 or 300-2 with the impedance inside communication device 300-1 or 300-2. Play a role.

  The backup storage battery 230 provided as a backup power source that outputs a backup direct current to the current distribution device 100 is charged to a fixed predetermined voltage by the charging unit 240. When the direct current is not supplied from the rectifying unit 210 to the current distribution device 100 due to, for example, a power failure of the commercial power supply 400, the backup storage battery 230 discharges the direct current stored in the backup storage battery 230 to thereby convert the direct current into the current distribution device. To 100.

  Further, when a short circuit accident occurs in the communication module 310-1 included in the communication device 300-1, the rectifying unit 210 of the rectifying device 200, the capacitor 220 and the backup storage battery 230 provided on the output side of the rectifying device 200, A direct current flows from the capacitor 120 of the current distribution device 100, the capacitor 320-1 of the communication device 300-1, and the capacitor 320-2 of the communication device 300-2 to the communication module 310-1. When the sum of these DC currents is equal to or greater than the interrupting rated current of the fuse 110-1, the communication device 300-1 and the rectifying device 200 are disconnected by the melting of the fuse 110-1, and the communication device 300 is disconnected. -1 is protected.

In the example illustrated in FIG. 6, the number of communication devices 300-1 to 300-2 is “2” as an example, but the number of communication devices 300-1 to 300-2 is “3” or more. But you can. Therefore, the current distribution device 100 may branch to a large number of communication devices 300-1 to 300-2 and supply a direct current.
Takashi Takeda et al., “Research and Development of Power Supply System and Communication Power Supply”, NTT Technical Journal, November 2001, pages 44-49

  When a short circuit accident occurred in the communication module 310-1, it was prorated according to each impedance of the wiring from each of the rectifying unit 210, the capacitor 220, the backup storage battery 230, the capacitor 120, and the capacitor 320-2 to the short circuit point. Each direct current flows to the communication module 310-1. When the sum of the current values of the respective DC currents is equal to or higher than the rated breaking current of the fuse 110-1, that is, when an overcurrent flows, the fuse 110-1 is blown.

  In general, the wiring distance from the rectifying device 200 to the current distribution device 100 and the wiring distance from the current distribution device 100 to each of the communication devices 300-1 and 300-2 are the installation environment of the current distribution system (for example, The position of the machine room where the rectifier 200 and the current distribution device 100 are installed, the position of the communication machine room where the communication devices 300-1 and 300-2 are installed, and the like.

  For example, the wiring distance from the rectifying device 200 to the current distribution device 100 may reach several tens of meters. In addition, each wiring distance from the current distribution device 100 to the communication device 300-1 or 300-2 may be several meters. Under such a configuration, for example, when a short-circuit accident occurs in the communication module 310-1, the current values of the discharge currents from the capacitor 120 and the capacitor 320-2 do not occur when a short-circuit accident occurs. The direct current supplied to the communication device 300-2 is much larger (for example, several tens of times). Therefore, the output voltage output from the current distribution device 100 to the communication module 310-2 varies greatly. Since the output voltage is input to the communication device 300-2 that is operating normally, the input voltage of the communication device 300-2 that is operating normally also changes as the output voltage varies.

  Therefore, according to the technique shown in FIG. 6, the input voltage that is input from the current distribution device 100 to the communication device 300-2 is within the input voltage range in which the communication device 300-2 can operate normally. When deviating from the voltage range, there is a problem that the normally operating communication device 300-2 stops.

  An object of this invention is to provide the electric current distribution apparatus which solves the subject mentioned above.

  In order to solve the above problems, a current distribution device of the present invention is a current distribution device that distributes a direct current output from a rectifier and supplies the distributed direct current to each of a plurality of load devices. A plurality of DC devices that are connected to each of the load devices and that block the supply of the distributed DC current to the connected load devices based on the current value of the DC current from the distributed rectifier. All of the plurality of blocking sections and one end are connected by a wiring having a wiring distance shorter than the wiring connected from the rectifying device to the plurality of blocking sections, and the other end is grounded. A capacitor and one end of the connection terminals connected in parallel to the capacitor and shorter than the wiring connected from the rectifier to the plurality of blocking sections Distance is connected to the plurality of blocking portions by wire with, and a large-capacity capacitor having a large storage capacity than the capacitor.

  In addition, the current distribution device of the present invention is connected to the capacitor and the large-capacity capacitor in parallel, and one end of the connection terminals connected in parallel is connected from the rectifier to the plurality of blocking portions. A storage battery that is connected to the plurality of blocking portions by wiring having a shorter wiring distance and outputs a voltage that is smaller in variation than the voltage discharged by each of the capacitor and the large-capacitance capacitor may be included.

  Further, the current distribution device of the present invention is connected in parallel with the capacitor instead of the large-capacity capacitor, and one end of the connection terminals connected in parallel is connected from the rectifier to the plurality of blocking portions. A storage battery that is connected to a plurality of interrupting parts by a wiring having a shorter wiring distance than the wiring, and that outputs a voltage with a smaller fluctuation than a voltage discharged by the capacitor, and a charging part that charges the storage battery. Also good.

  According to the present invention, in the current distribution device that distributes the direct current output from the rectifier and supplies the distributed direct current to each of the plurality of load devices, each of the load devices is connected and distributed. Based on the current value of the direct current from the rectifier, a plurality of interrupters that respectively cut off the supply of the distributed direct current to the connected load device, and connected from the rectifier to the plurality of interrupters All of the plurality of blocking portions and one end are connected by a wiring having a shorter wiring distance than the wiring, and the other end of the capacitor is connected to the ground, the capacitor is connected in parallel, and the connection terminal is connected in parallel. One end of which is connected to multiple shut-off units by wires having a shorter wiring distance than the wire connected from the rectifier to the multiple shut-off units, and is larger than the capacitor Due to a structure having a large-capacity capacitor having a storage capacity, even when a short circuit accident in one of the plurality of load devices has occurred, it is possible to avoid the stop of the load device is operating normally.

(Embodiment 1)
Hereinafter, a current distribution system (including a current distribution device) according to Embodiment 1 of the present invention will be described. First, the overall configuration of the current distribution system according to the first embodiment will be described.

  As shown in FIG. 1, the current distribution system includes a current distribution device 1, a rectifying device 2, a plurality of communication devices 3-1 to 3-2, and a commercial power source 4. In this explanation example, the case where the number of communication devices 3-1 to 3-2 is “2” will be described as an example, but the number of communication devices 3-1 to 3-2 may be “3” or more. .

  The current distribution device 1 distributes the direct current output from the rectifier 2 and supplies the distributed direct current to each of the communication devices 3-1 to 3-2. Note that the DC currents that the current distribution device 1 supplies to the communication devices 3-1 and 3-2 are DC currents that can be operated by the communication devices 3-1 and 3-2, respectively.

  The input voltage input from the current distribution device 1 to the communication devices 3-1 to 3-2 is an allowable input voltage range in which the communication devices 3-1 to 3-2 can operate normally. Is within. If the input voltage to the communication devices 3-1 to 3-2 is lower than the allowable input voltage range, the communication devices 3-1 to 3-2 may stop. Further, if the input voltage to the communication devices 3-1 to 3-2 is higher than the allowable input voltage range, the communication devices 3-1 to 3-2 may be destroyed.

  The rectifier 2 generates a direct current by rectifying the alternating current input from the commercial power supply 4, and outputs the generated direct current to the current distribution device 1.

  The communication devices 3-1 to 3-2 are “load devices” that each execute a predetermined communication operation using the direct current supplied from the current distribution device 1. The communication devices 3-1 to 3-2 may be any devices as long as they serve as an output load for the direct current supplied from the current distribution device 1.

  In addition, the input terminal for inputting the direct current which the communication apparatuses 3-1 to 3-2 have is the same as a general input terminal. That is, the input terminals of the communication devices 3-1 to 3-2 are configured by two electrodes (for example, a positive electrode and a negative electrode), and a direct current is input to one electrode and the other electrode is grounded. The potential of the other electrode is kept at “0”.

  Next, the configuration of the current distribution device 1 of Embodiment 1 will be described in detail.

  The current distribution device 1 includes a plurality of blocking units 11-1 to 11-2, a capacitor 12, and a large capacity capacitor 13. The number of blocking units 11-1 to 11-2 is the same as the number of communication devices 3-1 to 3-2 (in this example, “2”).

  The interruption | blocking part 11-1 or 11-2 is comprised by the fuse which blows, when the direct current more than a predetermined | prescribed electric current value flows, for example. The blocking unit 11-1 or 11-2 plays a role of connecting the rectifying device 2 and the communication device 3-1 or a role of connecting the rectifying device 2 and the communication device 3-2 in a state where it is not melted. Fulfill.

  In the melted state, the blocking unit 11-1 or 11-2 disconnects the connection between the rectifying device 2 and the communication device 3-1 or the connection between the rectifying device 2 and the communication device 3-2. It serves to avoid overcurrent flowing to -1 or 3-2.

  The blocking unit 11-1 or 11-2 has a “cutting rated current” in order to avoid an overcurrent flowing to the communication device 3-1 or 3-2. Here, the “breaking rated current” is a DC current level at which the blocking unit 11-1 or 11-2 is blown when flowing into the blocking unit 11-1 or 11-2.

  In other words, the blocking unit 11-1 or 11-2 is based on the level of the direct current from the rectifying device 2 distributed to itself (for example, “current value”) or the communication device 3-1 connected to itself. The supply of direct current to 3-2 is cut off.

  More specifically, the blocking unit 11-1 or 11-2 is energy (for example, Joule heat) proportional to the square of the direct current flowing through itself, that is, the direct current from the rectifier 2 distributed to itself. Blows when is greater than the breaking capacity. For example, when the blocking unit 11-1 is melted, the connection between the rectifying device 2 and the communication device 3-1 is disconnected. Therefore, the supply of direct current to the communication device 3-1 is interrupted, and the communication device 3-1 is protected. In addition, interruption | blocking capacity | capacitance is the level of the energy which the interruption | blocking part 11-1 or 11-2 fuses.

  The capacitor 12 is configured by a general capacitor such as a single plate type, a swivel type, and a laminated type. The capacitor 12 stores the direct current output from the rectifier 2.

  Further, the capacitor 12 supplies a direct current to the communication device 3-1 or 3-2 by discharging the stored charge.

  Further, when a “short circuit accident” occurs in any of the communication devices 3-1 to 3-2, the capacitor 12 is disconnected from the communication device 3-1 to 3-2 in which the short circuit accident has occurred. A direct current for fusing parts 11-1 to 11-2 is supplied.

  The “short-circuit accident” referred to here means that, for example, due to the occurrence of a failure or the like, the wirings connected to the positive electrode and the negative electrode constituting the input terminal of the communication module 31-1 are in contact with each other. The impedance of the communication module 31-1 is extremely reduced.

  In addition, one end of the two connection terminals of the capacitor 12 is cut off by the wiring having a shorter wiring distance than the wiring connected from the rectifying device 2 to the blocking sections 11-1 to 11-2. ~ 11-2 are all connected. The other end of the two connection terminals of the capacitor 12 is grounded.

  The large capacity capacitor 13 stores the direct current output from the rectifier 2. The large-capacitance capacitor 13 supplies a direct current to the communication devices 3-1 to 3-2 by discharging the stored charge.

  The large capacity capacitor 13 is connected in parallel with the capacitor 12. That is, one end of the two connection terminals of the large-capacitance capacitor 13 is connected to all of the blocking portions 11-1 to 11-2, and the other end is grounded. Of the connection terminals included in the large-capacitance capacitor 13, the connection terminals (one end) connected to the blocking units 11-1 to 11-2 are connected from the rectifier 2 to the blocking units 11-1 to 11-2. Are connected to the blocking portions 11-1 to 11-2 by a wiring having a shorter wiring distance than the wiring connected to.

  The large-capacitance capacitor 13 is constituted by a capacitor having a large storage capacity capable of storing a larger amount of charge than the capacitor 12. The large-capacitance capacitor 13 is a capacitor having a larger stored power density than the capacitor 12. The large-capacity capacitor 13 may be, for example, an electric double layer capacitor that is configured by an activated carbon electrode having organic molecules adsorbed on the surface thereof and can store a large capacity.

  Note that the capacitor 12 and the large-capacitance capacitor 13 each exhibit discharge voltage characteristics as shown in FIG.

  The capacitor 12 or the large-capacitance capacitor 13 starts discharging the charges stored in the capacitor 12 or the large-capacitance capacitor 13 when the charging is completed in a state where the terminal voltage V12 or V13 is charged to a constant voltage. The time when the capacitor 12 or the large-capacitance capacitor 13 starts discharging is set as the discharge starting time t0.

  The terminal voltages V12 and V13 of the capacitor 12 and the large-capacitance capacitor 13, respectively, begin to decrease rapidly immediately after the start of discharge. Then, as the elapsed time from the discharge start time t0 (hereinafter referred to as “discharge time t”) increases, the terminal voltage V12 of the capacitor 12 or the terminal voltage V13 of the large-capacitance capacitor 13 increases to a predetermined voltage value. And gradually approach.

  Next, the configuration of the rectifier 2 shown in FIG. 1 will be described.

  The rectifying device 2 includes a rectifying unit 21, a capacitor 22, a backup storage battery 23, and a charging unit 24.

  The rectifying unit 21 generates a direct current by rectifying the alternating current input from the commercial power supply 4 and outputs the generated direct current to the current distribution device 1. The capacitor 22 is connected to the output side of the rectifying device 2 and plays a role of matching the external impedance on the output side with the impedance inside the rectifying device 2.

  The backup storage battery 23 is configured by a secondary battery configured to be recharged and usable even when the stored charge is discharged, for example. The backup storage battery 23 may be any storage battery such as a lead storage battery, a nickel hydride battery, a nickel cadmium battery, or a lithium ion battery.

  The charging unit 24 is composed of, for example, a charger, and charges the backup storage battery 23 to a constant voltage. The method for charging the backup storage battery 23 by the charging unit 24 is not particularly limited. For example, floating charging that constantly maintains a charged state by a constant current constant voltage charging method or supply of a small current that compensates for the self-discharge of the backup storage battery 23 (Floating charge) may be used.

  Next, the configuration of the communication devices 3-1 and 3-2 will be described. Since the communication apparatuses 3-1 and 3-2 have the same configuration, the communication apparatus 3-1 will be described below as an example.

  The communication device 3-1 includes a communication module 31-1 and a capacitor 32-1.

  The communication module 31-1 performs a predetermined communication operation using the direct current supplied from the current distribution device 1. The capacitor 32-1 plays the same role as the capacitors 320-1 and 320-2 shown in FIG.

  Next, an operation in which the current distribution system according to the first embodiment having the above configuration distributes a direct current to the communication devices 3-1 to 3-2 will be described.

  First, the direct current distribution operation by the current distribution system of the first embodiment when no short-circuit accident has occurred in all the communication devices 3-1 to 3-2 will be described.

  The rectifying unit 21 of the rectifying device 2 generates a direct current by rectifying the alternating current input from the commercial power supply 4 and outputs the generated direct current to the current distribution device 1.

  The capacitor 12 and the large-capacitance capacitor 13 included in the current distribution device 1 are charged with a direct current from the rectifier device 2. When the charging period is sufficiently long, each of the capacitor 12 and the large-capacitance capacitor 13 is in a fully charged state in which charge is stored up to its accumulated charge capacity.

  Moreover, the current distribution device 1 distributes the direct current from the rectifier 2 by inputting the direct current output from the rectifier 2 to the cutoff units 11-1 and 11-2.

  In a state where the blocking sections 11-1 and 11-2 are not fused together, the rectifying device 2 and the communication device 3-1 are connected, and the rectifying device 2 and the communication device 3-2 are connected. Yes.

  For this reason, the direct current from the rectifier 2 distributed to the blocking unit 11-1 is supplied to the communication module 31-1. Furthermore, the capacitor 32-1 is charged by the direct current distributed to the blocking unit 11-1.

  Moreover, the direct current from the rectifier 2 distributed to the interruption | blocking part 11-2 is supplied to the communication module 31-2. Furthermore, the capacitor 32-2 is charged by the current distributed to the blocking unit 11-2.

  Next, a DC current distribution operation by the current distribution system according to the first embodiment when a short circuit accident occurs in any of the communication devices 3-1 to 3-2 will be described.

  When a short circuit accident occurs in the communication module 31-1 included in the communication device 3-1, the rectifier 21, the capacitor 22 and the backup storage battery 23 included in the rectifier 2, the capacitor 12 included in the current distribution device 1, and the large Each DC current apportioned according to each impedance of the wiring from the capacitor 13 and each of the capacitors 32-2 included in the communication device 3-2 to the short circuit point corresponds to the communication module 31- corresponding to the short circuit point. It flows to 1.

  When the sum of the current values of these direct currents becomes equal to or greater than the rated interrupting current of the interrupting unit 11-1, the interrupting unit 11-1 that supplies the direct current to the communication module 31-1 is blown out. By disconnection of the blocking unit 11-1, the connection between the communication module 31-1 in which a short circuit accident has occurred and the rectifying device 2 is disconnected, that is, the communication device 3-by stopping the supply of direct current to the communication device 3-1. 1 is protected.

  In general, the impedance of the wiring for supplying a direct current from the current supply source to the supply destination becomes smaller as the wiring distance becomes shorter. Therefore, the wiring distance (for example, 20 m) between the rectifying device 2 and the current distribution device 1 is larger than the wiring distance (for example, 2 m) between the current distribution device 1 and the communication device 3-1 or 3-2. When it is long, the impedance of the wiring between the current distribution device 1 and the communication device 3-1 or 3-2 is smaller than the impedance between the rectification device 2 and the current distribution device 1.

  Under such a configuration, among the rectifying unit 21, the capacitor 22, the backup storage battery 23, the capacitor 12, the large-capacity capacitor 13, and the capacitor 32-2, first, wiring with the communication module 31-1 in which a short-circuit accident has occurred. A direct current is supplied to the communication module 31-1 from the capacitor 12 and the large-capacitance capacitor 13 included in the current distribution device 1 having a short distance.

  Further, after the direct current is supplied from the capacitor 12 and the large-capacitance capacitor 13 of the current distribution device 1 having a short wiring distance to the communication module 31-1, the direct current from the rectifier 2 is changed to the communication modules 31-1 and 31. -2.

  When the sum of the current values of the DC currents mainly supplied from the capacitor 12 and the large-capacitance capacitor 13 becomes equal to or higher than the rated breaking current of the blocking unit 11-1, the blocking unit 11-1 is melted.

  The large-capacitance capacitor 13 included in the current distribution device 1 of the first embodiment includes the communication module 31-1 in which the short-circuit accident has occurred via the cutoff unit 11-1 in cooperation with the capacitor 12 after the occurrence of the short-circuit accident. DC current is supplied to Therefore, compared with a general current distribution device as shown in FIG. 6, more energy is supplied for fusing the cut-off part 11-1, and the cut-off part 11-1 is blown after the occurrence of a short-circuit accident. Can be shortened. That is, it is possible to quickly protect the communication device 3-1 in which the short circuit accident has occurred.

  Further, if the current distribution device 1 is configured in the same way as the general current distribution device 100 as shown in FIG. 6, the period from the occurrence of a short-circuit accident to the time before the breaking unit 11-1 is melted. The DC current supplied from the capacitor 12 and the rectifier 2 mainly flows to the communication module 31-1 having a very small impedance where a short circuit accident has occurred, rather than the communication module 31-2. Therefore, the input voltage to the normally operating communication module 31-2 is reduced during the period from the occurrence of the short circuit accident to before the blowout of the blocking unit 11-1.

  However, in the current distribution device 1 of the first embodiment, the large-capacitance capacitor 13 is connected in parallel with the capacitor 12. The large-capacitance capacitor 13 cooperates with the capacitor 12 in the period from immediately after the occurrence of the short-circuit accident to before the blocking unit 11-1 is blown, and the communication module 31 of the communication device 3-2 operating normally. DC current is also supplied to -2.

  Therefore, even in the case where the operation of the communication device 3-2 cannot be maintained with only the direct current supplied from the capacitor 12 only during the transient period from the occurrence of the short-circuit accident to the melting of the cutoff unit 11-1, the large-capacity capacitor By supplying the direct current from 13, it is possible to suppress a reduction in the direct current voltage input from the current distribution device 1 to the communication module 31-2. That is, when the fluctuation of the output voltage of the current distribution device 1 is reduced, the input voltage to the communication device 3-2 is less likely to deviate from the input voltage allowable range. Therefore, it is possible to avoid the stop of the communication device 3-2 operating normally.

  It should be noted that a much larger overcurrent (for example, several tens of times) than normal flows from the time of occurrence of a short circuit accident to the melting of the blocking section 11-1. Due to this overcurrent, magnetic energy is accumulated in the inductance of the impedances of the respective wirings that mutually connect the current distribution device 1, the rectifier device 2, and the communication devices 3-1 and 3-2.

  Then, after the cut-off part 11-1 is melted, the accumulated magnetic energy is stored in the capacitor 12 and the large-capacitance capacitor 13 included in the current distribution device 1, the capacitor 22 included in the rectifier 2, and the communication device 3. -2 is emitted while resonating with each capacitor 32-2. For this reason, the input voltage to the normally operating communication device 3-2 temporarily rises during the period from when the blocking unit 11-1 is melted to when the resonance ends.

  However, a large-capacity capacitor 13 having a larger storage capacity than the capacitor 12 is connected to the current distribution device 1 in parallel with the capacitor 12. That is, when the capacitor 12 and the large-capacitance capacitor 13 cooperate with each other, the magnetic energy released from more wires can be stored as compared with the case where only the capacitor 12 is used.

Therefore, the release of magnetic energy after the cutting of the blocking unit 11-1 that causes the input voltage to the normally operating communication device 3-2 to increase is quickly terminated. For this reason, an increase in the input voltage to the communication device 3-2 operating normally can be suppressed, that is, the input voltage is unlikely to deviate from the input voltage allowable range of the communication device 3-2.
(Embodiment 2)
Next, the current distribution system of Embodiment 2 will be described.

  As shown in FIG. 3, the overall configuration of the current distribution system according to the second embodiment is basically the same as the configuration shown in FIG.

  However, the current distribution device 1 </ b> A of the second embodiment includes a “storage battery 14” in addition to the configuration of the current distribution device 1 of the first embodiment.

  The storage battery 14 is connected to the capacitor 12 and the large capacity capacitor 13 in parallel. That is, one end of the two connection terminals of the storage battery 14 is connected to the connection terminals to the blocking portions 11-1 to 11-2 among the connection terminals of the capacitor 12 and the large-capacitance capacitor 13, and the remaining ones. The other end is connected to the ground side connection terminal of the capacitor 12 and the large capacity capacitor 13. In addition, the connection terminal (one end) of the side connected with the interruption | blocking part 11-1 to 11-2 among the connection terminals which the storage battery 14 comprises is from the rectifier 2 to the interruption | blocking part 11-1 to 11-2. Are connected to the blocking portions 11-1 to 11-2 by wires having a shorter wiring distance than the wires connected to.

  The storage battery 14 is configured by a storage battery having a larger stored power density (for example, about 10 times) than the capacitor 12 and the large-capacity capacitor 13.

  In this explanation example, a case where a lead storage battery generally used as an inexpensive storage battery is used as the storage battery 14 will be described as an example. However, as the storage battery 14, for example, a storage battery (for example, a lithium ion battery) having a higher discharge rate or higher power density than the lead storage battery may be used.

  The storage battery 14 (lead storage battery) exhibits a discharge voltage characteristic as shown in FIG. 4, for example, when a constant direct current is discharged. Note that “CA” in FIG. 4 indicates the current value of the discharge current corresponding to the rated capacity.

  The terminal voltage V14, which is the voltage between the terminals of the storage battery 14, is maintained at a substantially constant value with respect to the change in the discharge time t until the discharge time t that has elapsed from the discharge start time reaches a predetermined time. The voltage characteristic is flat.

  Further, when the storage battery 14 continues the discharge operation of a constant direct current, after the discharge time t has passed a predetermined time, the terminal voltage V14 of the storage battery 14 decreases rapidly as the discharge time t increases.

  The storage battery 14 outputs a terminal voltage V14 having a smaller variation than the terminal voltages V12 and V13 shown in FIG.

  Next, an operation in which the current distribution system according to the second embodiment having the above configuration distributes a direct current to the communication devices 3-1 to 3-2 will be described.

  When no short circuit accident has occurred in all the communication devices 3-1 to 3-2, the direct current distribution operation performed by the current distribution system of the second embodiment is basically the same as the operation shown in the first embodiment. is there.

  That is, the direct current output from the rectifying unit 21 charges the capacitor 12, the large-capacity capacitor 13, and the storage battery 14. The direct current from the rectifying unit 21 is distributed to the blocking units 11-1 and 11-2, and the distributed direct currents are supplied to the communication modules 31-1 and 31-2. Further, the direct currents distributed to the blocking units 11-1 and 11-2 charge the capacitors 32-1 and 32-2, respectively.

  Next, a DC current distribution operation by the current distribution system according to the second embodiment when a short circuit accident occurs in any of the communication devices 3-1 to 3-2 will be described.

  When a short circuit accident occurs in the communication module 31-1 included in the communication device 3-1, the rectifying unit 21, the capacitor 22 and the backup storage battery 23 included in the rectifier 2, the capacitor 12 included in the current distribution device 1 A, large The direct current apportioned according to each impedance from the capacitor 13 and the storage battery 14 and each of the capacitors 32-2 included in the communication device 3-2 to the short circuit point corresponds to the communication module 31- corresponding to the short circuit point. It flows to 1.

  When the sum of the current values of these direct currents becomes equal to or greater than the rated interrupting current of the interrupting unit 11-1, the interrupting unit 11-1 that supplies the direct current to the communication module 31-1 is blown out. The connection between the communication module 31-1 in which the short circuit accident has occurred and the rectifying device 2 is disconnected by the melting of the blocking unit 11-1. Therefore, the supply of direct current to the communication device 3-1 is stopped, and the communication device 3-1 is protected.

  In addition, the wiring distance (for example, 20 m) between the rectifier 2 and the current distribution device 1A is larger than the wiring distance (for example, 2 m) between the current distribution device 1A and the communication device 3-1 or 3-2. When the length is long, the impedance of the wiring between the current distribution device 1A and the communication device 3-1 or 3-2 is smaller than the impedance between the rectification device 2 and the current distribution device 1A.

  Under such a configuration, first of all, among the rectifying unit 21, the capacitor 22, the backup storage battery 23, the capacitor 12, the large capacity capacitor 13, the storage battery 14, and the capacitor 32-2, a short circuit accident occurs. A direct current is supplied to the communication module 31-1 from the capacitor 12, the large-capacity capacitor 13 and the storage battery 14 included in the current distribution device 1 </ b> A having a short wiring distance with the generated communication module 31-1.

  Furthermore, after supplying direct current from the capacitor 12, the large-capacitance capacitor 13, and the storage battery 14 of the current distribution device 1A with a short wiring distance to the communication module 31-1, the direct current from the rectifier 2 is changed to the communication module 31-1. And 31-2.

  When the sum of the current values of the DC currents mainly supplied from the capacitor 12, the large-capacitance capacitor 13, and the storage battery 14 is equal to or higher than the cutoff rated current of the cutoff unit 11-1, the cutoff unit 11-1 is blown. To do.

  The storage battery 14 included in the current distribution device 1A of the second embodiment includes a communication module in which the short-circuit accident has occurred via the blocking unit 11-1 in cooperation with the capacitor 12 and the large-capacitance capacitor 13 after the occurrence of the short-circuit accident. DC current is supplied to 31-1. Therefore, compared with the general current distribution device 100 as shown in FIG. 6, more energy is supplied for fusing the cut-off part 11-1, and the cut-off part 11-1 is blown after the occurrence of a short-circuit accident. The period until it can be shortened. That is, it is possible to quickly protect the communication device 3-1 in which the short circuit accident has occurred.

  Further, if the current distribution device 1A is configured in the same manner as the general current distribution device 100 as shown in FIG. 6, the period from the occurrence of the short-circuit accident to before the cutoff portion 11-1 is melted. The DC current supplied from the capacitor 12 and the rectifier 2 mainly flows to the communication module 31-1 having a very small impedance where a short circuit accident has occurred, rather than the communication module 31-2. Therefore, the input voltage to the normally operating communication module 31-2 is reduced during the period from the occurrence of the short circuit accident to before the blowout of the blocking unit 11-1.

  However, in the second embodiment, the storage battery 14 having a larger stored power density (for example, about 10 times) than the capacitor 12 and the large capacity capacitor 13 is connected in parallel with the capacitor 12 and the large capacity capacitor 13. And the said storage battery 14 is a communication apparatus which is operating normally in cooperation with the capacitor | condenser 12 and the large capacity capacitor | condenser 13 for the transitional period before the interruption | blocking part 11-1 melts | disconnects from the time of the occurrence of a short circuit accident. A direct current is supplied to the communication module 31-2 of 3-2.

  As illustrated in FIG. 4, the storage battery 14 has a flat discharge voltage characteristic. Therefore, even if a large overcurrent flows in a transitional period until the breaking part having a large breaking capacity is blown out of the plurality of breaking parts 11-1 to 11-2, other than the blown breaking part. It is possible to stably maintain the supply of a direct current capable of operating the normally operating communication devices 3-1 to 3-2 connected to the blocking unit.

  In addition, since the overcurrent much larger (for example, several tens of times) than the normal time flows after the occurrence of the short-circuit accident and before the cutoff of the blocking unit 11-1, the current distribution device 1A and the rectifying device 2 Magnetic energy is accumulated in the inductance of the impedances of the respective wirings that mutually connect the communication devices 3-1 and 3-2.

  And after melt | disconnection of the interruption | blocking part 11-1, the said accumulate | stored magnetic energy is the capacitor | condenser 12 which the current distribution apparatus 1A comprises, the large capacity capacitor | condenser 13, the capacitor | condenser 22 which the rectifier 2 comprises, and the communication apparatus 3-2. Is emitted while resonating with each of the capacitors 32-2 included in the. For this reason, the input voltage to the normally operating communication device 3-2 temporarily rises during the period from when the blocking unit 11-1 is melted to when the resonance ends.

  However, the storage battery 14 is constituted by a power source and a resistor that perform a function of supplying a DC voltage when represented by an equivalent circuit. With the generation of Joule heat due to this resistance, the magnetic energy released from the wiring is consumed.

Therefore, the release of magnetic energy after the cutting of the blocking unit 11-1 that causes the input voltage to the normally operating communication device 3-2 to increase is quickly terminated. For this reason, an increase in the input voltage to the communication device 3-2 operating normally can be suppressed, that is, the input voltage is unlikely to deviate from the input voltage allowable range of the communication device 3-2.
(Embodiment 3)
Next, a current distribution system according to Embodiment 3 will be described.

  As shown in FIG. 5, the configuration of the current distribution system of the third embodiment is basically the same as the configuration shown in the first or second embodiment. However, the current distribution system according to the third embodiment includes a current distribution device 1B.

  The current distribution device 1B of the third embodiment is configured so as not to have the large-capacitance capacitor 13 in the current distribution device 1A shown in FIG.

  In addition, the current distribution device 1B includes a charging unit 15 for charging the storage battery 14 illustrated in FIG.

  The storage battery 14 of Embodiment 3 is connected in parallel with the capacitor 12 and supplies a direct current to the plurality of communication devices 3-1 to 3-2.

  In addition, although the method in which the charging unit 15 charges the storage battery 14 is not particularly limited, for example, a general charging method such as a constant current constant voltage charging method or a floating charging method may be used.

  The storage battery 14 plays a role of backing up the supply of direct current from the current distribution device 1B to the communication devices 3-1 to 3-2.

  Moreover, the storage battery 14 shows the discharge voltage characteristic shown in FIG. Therefore, the storage battery 14 plays a role of suppressing transient fluctuations in the output voltage that occurs when any one of the communication devices 3-1 to 3-2 is short-circuited.

  In addition, when there are a plurality of current distribution devices 1B, the storage battery 14 is provided in each of the current distribution devices 1B, and direct current is supplied to the communication devices 3-1 to 3-2 connected to the current distribution devices 1B. Perform supply backup. In this case, it is possible to perform backup of appropriate DC current supply according to the capacities of the communication devices 3-1 to 3-2 individually connected to each of the current distribution devices 1B.

  Furthermore, the rectifier 2 of the third embodiment is configured not to include the backup storage battery 23 and the charging unit 24 included in the first and second embodiments.

  Next, an operation in which the current distribution system of the third embodiment having the above configuration distributes a direct current to the communication devices 3-1 to 3-2 will be described.

  When no short-circuit accident has occurred in all the communication devices 3-1 to 3-2, the direct current distribution operation performed by the current distribution system of the third embodiment is the same as the operations described in the first and second embodiments. .

  That is, the direct current output from the rectifying unit 21 is distributed to the cutoff units 11-1 and 11-2, and each distributed direct current is supplied to the communication modules 31-1 and 31-2. Further, the direct currents distributed to the blocking units 11-1 and 11-2 charge the capacitors 32-1 and 32-2, respectively.

  Next, a DC current distribution operation by the current distribution system according to the third embodiment when a short circuit accident occurs in any of the communication devices 3-1 to 3-2 will be described.

  When a short circuit accident occurs in the communication module 31-1 included in the communication device 3-1, the rectifier 21 and the capacitor 22 included in the rectifier 2, the capacitor 12 and the storage battery 14 included in the current distribution device 1B, communication A DC current that is prorated according to each impedance of the wiring from each of the capacitors 32-2 included in the device 3-2 to the short circuit point flows to the communication module 31-1 corresponding to the short circuit point.

  When the sum of the current values of these direct currents becomes equal to or greater than the rated breaking current of the blocking unit 11-1, the blocking unit 11-1 is blown. Then, the connection between the communication module 31-1 in which the short-circuit accident has occurred and the rectifying device 2 is disconnected due to the melting of the blocking unit 11-1, that is, the communication device is stopped by stopping the supply of direct current to the communication device 3-1. 3-1 is protected.

  In addition, the wiring distance (for example, 20 m) between the rectifier 2 and the current distribution device 1B is larger than the wiring distance (for example, 2 m) between the current distribution device 1B and the communication device 3-1 or 3-2. In the case of being long, the impedance between the current distribution device 1B and the communication device 3-1 or 3-2 is smaller than the impedance between the rectification device 2 and the current distribution device 1B.

  Under such a configuration, among the rectifying unit 21, the capacitor 22, the capacitor 12, the storage battery 14, and the capacitor 32-2, first, the wiring distance to the communication module 31-1 in which the short circuit accident has occurred. DC current is supplied to the communication module 31-1 from the capacitor 12 and the storage battery 14 included in the short current distribution device 1B.

  Furthermore, after supplying the direct current from the capacitor 12 and the storage battery 14 of the current distribution device 1B having a short wiring distance to the communication module 31-1, the direct current from the rectifier 2 is supplied to the communication modules 31-1 and 31-2. Supplied with.

  And when the current value of the direct current mainly supplied from the capacitor 12 and the storage battery 14 becomes equal to or higher than the cutoff rated current of the cutoff unit 11-1, the cutoff unit 11-1 is blown out.

  After the occurrence of a short circuit accident, the storage battery 14 included in the current distribution device 1B of the third embodiment is linked to the communication module 31-1 in which the short circuit accident has occurred via the blocking unit 11-1 in cooperation with the capacitor 12. Supply direct current. Therefore, compared with the general current distribution device 100 as shown in FIG. 6, more energy is supplied for fusing the cut-off part 11-1, and the cut-off part 11-1 is blown after the occurrence of a short-circuit accident. The period until it can be shortened. That is, it is possible to quickly protect the communication device 3-1 in which the short circuit accident has occurred.

  Further, if the current distribution device 1B is configured in the same way as the general current distribution device 100 as shown in FIG. 6, the period from the occurrence of the short-circuit accident to the time before the breaker 11-1 is melted. The DC current supplied from the capacitor 12 and the rectifier 2 mainly flows to the communication module 31-1 having a very small impedance where a short circuit accident has occurred, rather than the communication module 31-2. Therefore, the input voltage to the normally operating communication module 31-2 is reduced during the period from the occurrence of the short circuit accident to before the blowout of the blocking unit 11-1.

  However, as shown in FIG. 4, according to the discharge voltage characteristics of the storage battery 14, the fluctuation of the terminal voltage V14 immediately after the start of discharge is smaller than the terminal voltage V12 of the capacitor 12 having the discharge voltage characteristics shown in FIG.

  As a result, in a transitional period from the occurrence of the short-circuit accident to before the breaking of the cutoff unit 11-1, the fluctuation of the output voltage output from the current distribution device 1B, that is, the input to the communication device 3-2. The fluctuation of the input voltage is reduced, and the input voltage is less likely to deviate from the input voltage allowable range of the communication device 3-2. Thereby, even when a short circuit accident occurs in the communication device 3-1, it is possible to avoid the stop of the communication device 3-2 operating normally.

  As described above, the storage battery 14 included in the current distribution device 1B plays a role of backing up the supply of direct current to the communication devices 3-1 to 3-2 by the current distribution device 1B, and at the time when a short-circuit accident occurs. It plays a role in suppressing transient fluctuations in output voltage.

  In addition, since the overcurrent much larger (for example, several tens of times) than the normal time flows from the time of occurrence of the short-circuit accident to before the cutting of the blocking unit 11-1, the current distribution device 1B and the rectifying device 2 Magnetic energy is accumulated in the inductance of the impedances of the respective wirings that mutually connect the communication devices 3-1 and 3-2.

  Then, after the cut-off part 11-1 is melted, the accumulated magnetic energy is provided in the capacitor 12 included in the current distribution device 1B, the capacitor 22 included in the rectifier 2, and the communication device 3-2. It is emitted while resonating with each of the capacitors 32-2. For this reason, the input voltage to the normally operating communication device 3-2 temporarily rises during the period from when the blocking unit 11-1 is melted to when the resonance ends.

  However, the storage battery 14 is constituted by a power source and a resistor that perform a function of supplying a DC voltage when represented by an equivalent circuit. With the generation of Joule heat due to this resistance, the magnetic energy released from the wiring is consumed.

  Therefore, the release of magnetic energy after the cutting of the blocking unit 11-1 that causes the input voltage to the normally operating communication device 3-2 to increase is quickly terminated. For this reason, an increase in the input voltage to the communication device 3-2 operating normally can be suppressed, that is, the input voltage is unlikely to deviate from the input voltage allowable range of the communication device 3-2.

  Moreover, since the storage battery 14 of Embodiment 3 also has the effect of suppressing voltage fluctuations immediately after the start of discharge due to a short circuit, in order to suppress fluctuations in the input voltage to the normally operating communication device 3-2 at the time of the short circuit. It is possible to reduce the space and cost for installing the power source (for example, storage battery).

  As described above, according to the current distribution system of the present invention, when a short circuit accident occurs in any of the plurality of communication apparatuses 3-1 to 3-2, the communication apparatuses 3-1 to 3-1 in which the short circuit accident has occurred. While protecting 3-2, the stop of the other communication apparatuses 3-1 to 3-2 operating normally can be avoided.

It is a figure which shows the structure of the current distribution system according to Embodiment 1 of this invention. It is a figure which shows the discharge voltage characteristic of a capacitor | condenser and a large-capacity capacitor, respectively. It is a figure which shows the structure of the current distribution system according to Embodiment 2 of this invention. It is a figure which shows the discharge voltage characteristic of a storage battery. It is a figure which shows the structure of the current distribution system according to Embodiment 3 of this invention. It is a figure which shows an example of a structure of a general electric current distribution system.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 1A, 1B Current distribution device 11-1, 11-2 Blocking part 12, 22, 32-1, 32-2 Capacitor 13 Large capacity capacitor 14 Storage battery 15, 24 Charging part 2 Rectifier 21 Rectifier 23 Backup storage battery 3 -1, 3-2 Communication device 31-1, 31-2 Communication module 4 Commercial power supply

Claims (3)

A current distribution device that distributes a direct current output from a rectifier and supplies the distributed direct current to each of a plurality of load devices,
A plurality of cut-offs connected to each of the load devices and for cutting off the supply of the distributed DC current to the connected load devices based on the current value of the DC current from the distributed rectifier And
All of the plurality of blocking sections and one end are connected by wiring having a shorter wiring distance than wiring connected from the rectifier to the plurality of blocking sections, and the other end is grounded,
The plurality of wires are connected in parallel with the capacitor, and one end of the connection terminals connected in parallel has a shorter wiring distance than a wire connected from the rectifier to the plurality of blocking portions. And a large-capacity capacitor having a larger storage capacity than that of the capacitor.   A wiring distance that is connected in parallel to the capacitor and the large-capacitance capacitor, and one end of the connection terminals connected in parallel is shorter than the wiring connected from the rectifier to the plurality of blocking portions 2. A storage battery that is connected to the plurality of cut-off portions by a wiring having a voltage, and that outputs a voltage whose fluctuation is smaller than a voltage discharged from each of the capacitor and the large-capacitance capacitor. The current distribution device described. Instead of the large capacitor,
The plurality of wires are connected in parallel with the capacitor, and one end of the connection terminals connected in parallel has a shorter wiring distance than a wire connected from the rectifier to the plurality of blocking portions. A storage battery that is connected to the shut-off portion of the capacitor and outputs a voltage having a smaller fluctuation than a voltage discharged by the capacitor;
The current distribution device according to claim 1, further comprising: a charging unit that charges the storage battery.

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