JP4170939B2 - Power supply system - Google Patents

Description

  The present invention relates to a power supply circuit, and more particularly to a power supply system in which a power source is shared by distributing and supplying power supplied to a main transmission power supply and an ether power supply power supply.

  Particularly, in the backbone transmission device, for example, even if a failure occurs in the communication port of the downstream terminal system, the backbone communication data and the operation of the monitoring / control system must not be affected. In general, power supply system power supplies are separated and supplied separately. However, the ratio of the power supply unit to the demand for downsizing and high efficiency of the device is increasing. For this reason, there is an increasing need to share power supplies for the backbone transmission system and the ether power supply system.

A conventional power supply system of this type includes at least a hub, a plurality of nodes, a communication cable connecting the plurality of nodes to a hub that provides data communication, and at least a part of the plurality of nodes via the communication cable. There is a power distribution system that operates to supply some operating power (see, for example, Patent Document 1).
JP-T-2002-534937 (pages 95 and 96, FIG. 1A, FIG. 1B)

  The invention described in Patent Document 1 described above relates to the structure and control method of Ethernet power supply. However, the power supply of the main signal processing unit and the monitoring control unit in the backbone transmission system and the power supply of the power supply system are provided. It does not describe the problems that occur when sharing.

  Conventionally, in the backbone transmission system, in order to ensure reliability, the Ether power supply power supply portion is separated and independent from the main portion of the backbone transmission line. However, in order to reduce the size and increase the efficiency of the apparatus, it is necessary to share it with the main part of the transmission apparatus (core transmission apparatus).

In the following, issues are listed in bullets.
1. When the main system power supply of the backbone transmission apparatus and the Ethernet power supply system power supply are shared, the power supply capability also changes depending on the surrounding environment where the apparatus is located. If the power supply to the main transmission equipment main part is insufficient, the power supply capacity is judged including the equipment environment, and it is expected to cause bit errors and communication failures due to voltage drop and power noise of the main part of the transmission equipment. The

  2. Further, for example, if a failure or the like occurs on the Ethernet power supply side (downstream communication path) and an abnormally high current flows on the Ethernet cable or in the terminal, the transmission device uses the power lost here. If power supply to the main part is hindered or power supply noise is generated, there is a possibility of causing a bit error or communication interruption.

  3. In order to eliminate as much as possible the disconnection between the main part of the backbone transmission apparatus and the terminal operating by the downstream Ethernet power supply, it is necessary to evenly distribute the power that can be supplied by the Ethernet to the ports to which the terminals are connected.

  4). In order to eliminate as much as possible the disconnection between the main part of the backbone transmission device and the terminal operating by downstream Ethernet power supply, the power that can be supplied by Ethernet is distributed to each port connected to the terminal according to the preset power consumption. There is a need.

  5. In order to minimize the communication disconnection between the main part of the backbone transmission equipment and the terminals operating by downstream Ethernet power supply, the total power consumption set for the ports connected to the terminals is the Ethernet power supply. Even when the power that can be supplied to the power supply is exceeded, it may be necessary to supply power to a specific e-support after the stable supply of power to the main part of the transmission apparatus.

  The present invention has been made in view of such problems, and a power supply system that shares the power supply unit of the Ether power supply unit and the main part of the transmission apparatus while ensuring reliability in the backbone transmission system. It is intended to provide.

(1) The invention according to claim 1 is characterized in that one power source, at least one power circuit for supplying power from the power source to the main transmission apparatus main part, and the total supply power Po from the ambient temperature of the power source. with calculating, from the current of the voltage of the power supply source to said trunk transmission device main unit, and the total supply power calculation means for calculating the supply power Pt to the backbone transmission apparatus main unit, receives power from the power supply source , at least one of the ether feed circuit, to that from said total supply power Po minus the power Pt supplied to the trunk transmission apparatus main unit, and Ethernet feeding power calculated from the voltage and current of the Ether feed circuit comparison, a Ether feeding power calculating means for outputting a control signal for turning on / off the ether feed circuit to the Ethernet power supply control circuit according to the comparison result, the power supply A power supply switch for turning on / off the Ethernet power supply circuit supplied to the network from a network; an Ether power supply control circuit for controlling on / off of the power supply switch in response to a control signal from the Ethernet power supply calculation means; It is characterized by comprising.
(2) The invention according to claim 2 is characterized in that the Ethernet power supply control circuit cuts off a power supply switch of the corresponding Ethernet power supply circuit when detecting an abnormal current.
(3) The invention according to claim 3 is characterized in that the Ethernet power supply control circuit equally distributes the power that can be supplied to the Ethernet power supply circuit for each Ethernet power supply circuit.
(4) The invention described in claim 4 is characterized in that the power that can be supplied to the Ethernet power supply circuit is distributed according to the maximum power value assigned to each Ethernet power supply circuit.
(5) In the invention according to claim 5, when the power that can be supplied to the Ethernet power supply circuit is distributed according to the request of each Ethernet power supply circuit, the priority information is assigned to the Ethernet power supply circuit based on the priority information attached to each Ethernet power supply circuit. Distributing from a high Ether power supply circuit.

(1) According to the first aspect of the present invention, it is possible to provide a power supply system in which the reliability of the backbone transmission system is ensured and the Ethernet power supply power supply unit and the power supply unit of the main part of the transmission apparatus are shared. it can.
(2) According to the invention described in claim 2, when an abnormal current in the Ethernet power feeding system is detected, the power feeding switch of the corresponding Ether power feeding circuit can be shut off so that other devices are not affected. .
(3) According to the invention described in claim 3, the power can be evenly distributed to each Ethernet power feeding circuit by the Ethernet power feeding circuit.
(4) According to the invention described in claim 4, sufficient power is used in each power feeding circuit by distributing the power that can be supplied to each Ether power feeding circuit according to the maximum power value assigned to the Ether power feeding circuit. Can do.
(5) According to the invention described in claim 5, a priority order is given to the Ether power supply circuit, and power is distributed from the Ether power supply circuit having a high priority according to the priority information, so that a preferable power distribution can be achieved. Can be done.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a block diagram showing a first embodiment of the present invention. In the figure, reference numeral 1 denotes a power source that supplies power. The power source 1 supplies power by converting, for example, AC 100V into a voltage of -48V. Power is calculated from the power source 1 to the backbone transmission system and the Ethernet power feeding system. Power is supplied from the power source 1 to the backbone transmission system and the Ethernet power supply system. Reference numeral 3 denotes an ammeter that measures a current flowing through the backbone transmission apparatus system, and reference numeral 4 denotes a voltmeter that measures a voltage supplied to the backbone transmission apparatus system. Reference numeral 5 denotes a temperature sensor that measures the temperature of the environment in which the apparatus is installed.

  Reference numeral 6 denotes total supply power calculation means for receiving the output of the temperature sensor 5 and calculating the total supply power that can be supplied from the power source 1. The total supply power calculation means 6 calculates the amount of power supplied to the backbone transmission system from the output of the ammeter 3 and the output of the voltmeter 4. Further, the derating information related to the temperature is input to the total supply power calculation means 6.

  FIG. 2 is a diagram showing output current characteristics, and shows derating characteristics. In the figure, the horizontal axis represents temperature, and the vertical axis represents output current (%). If the output current increases at high temperatures, the power supply may be destroyed due to heat generation. Therefore, the value of current that can be output at 100% or less is used at high temperatures. Between the temperatures T1 and T2, the output current gradually decreases. Reference numeral 7 denotes a power supply circuit provided with at least one power supply that receives power from a power source and supplies power to the main part of the backbone transmission apparatus. N power supply circuits are used, and each converts a voltage of −48V into necessary voltages V1 to Vn.

  8 is the total supply power calculation means 6, which is obtained by subtracting the power supplied to the main part of the backbone transmission device from the total supply power value Po and the voltage and current of the Ethernet power supply circuit (described later). Ether power supply calculating means for calculating. As the total supply power calculation means 6 and the ether power supply power calculation means 8, for example, a CPU is used. An Ethernet power supply circuit 9 supplies power to the Ethernet power supply system. 10 is a power supply switch for turning on / off the power provided in the Ethernet power supply circuit 9, 11 is an ammeter for measuring the current flowing in the Ethernet power supply circuit 10, and 12 is a voltage for measuring the output voltage of the Ethernet power supply circuit. It is a total. As the above-mentioned ammeters 2, 3, and 11, for example, a method of measuring a voltage drop due to a small resistance, a measuring method using a Hall element arranged on a power supply wiring, or the like can be considered. As the voltmeters 4 and 12, a method of directly measuring a voltage, a method of performing comparison by a comparator, or the like is used. At least one ether power supply circuit 9 is provided.

  An Ethernet power supply control circuit 13 is connected to the Ethernet power supply circuit 14, the Ethernet power supply calculation means 8, and the main transmission device main part 15 and performs on / off control of a power supply switch provided in the Ethernet power supply circuit 9. An Ethernet power supply circuit 14 is connected to the power source 1 and supplies power for operating the Ethernet power supply control circuit 13. The Ethernet power supply circuit 14 generates a voltage Vm from -48V. Reference numeral 15 denotes a main transmission apparatus main part that is supplied with power from the power supply circuit 7 and includes a main signal processing part and a control / monitoring system processing part. The main transmission apparatus main part 15 is connected to a main transmission line 16 using an optical cable. Reference numeral 17 denotes an Ethernet power supply superimposing unit that is connected to the main transmission apparatus main unit 15 and the Ethernet power supply circuit 9 and transmits a signal to a port of each Ethernet (registered trademark of Fuji Xerox Co., Ltd.). The Ethernet power supply superimposing unit 17 supplies power to each port using, for example, a transformer. Reference numeral 18 denotes a terminal connected to each port. The operation of the system configured as described above will be described as follows.

  When the connector of the power source 1 is connected to the power line, the power source 1 converts AC 100V into a DC voltage of -48V. The voltage of −48 V is supplied to the main transmission apparatus main part 15 via the power supply circuit 7 and supplied to the Ethernet power supply circuit 9. The voltage of the power source 1 is supplied to the power circuit 7. Each power supply circuit 7 converts the input voltage −48V into a predetermined voltage Vi (i = 1 to n), and supplies it to the main transmission apparatus main part 15. The main transmission apparatus main part 15 receives the voltage of the power supply circuit 7 and performs main signal processing and control / monitoring system processing. A signal output from the main transmission apparatus main unit 15 is connected to the main transmission line 16 to transmit and receive signals.

  On the other hand, in the Ethernet power supply system, a signal on which a voltage is superimposed from the Ethernet power supply superimposing unit 17 is output from the port and received by the terminal 18. The signal from the terminal 18 is sent to the Ethernet power feeding superimposing unit 17 and exchanges signals with the main transmission device main unit 15 as necessary.

  In such a series of operations, the total supply power calculation means 6 receives the outputs of the ammeter 2 and the voltmeter 4 and the output of the temperature sensor 5 and calculates the total supply power Po. Next, the total supply power calculation means 6 receives the output of the ammeter 3 and the output of the voltmeter 4 and calculates the basic transmission system power Pt supplied to the main transmission apparatus main part 15. The Ether power supply calculating means 8 receives the supply power values Po and Pt from the total supply power calculating means 6 and calculates the power Pe that can be supplied by the Ethernet power supply system. The electric power Pe is expressed by the following equation.

Pe = Po-Pt
This power Pe is notified to the Ethernet power supply control circuit 13. The Ethernet power supply control circuit 13 turns on the power supply switches 10 of all the Ethernet power supply circuits 9 as long as the power used by all the Ethernet power supply circuits 9 does not exceed Pe. As a result, the Ethernet power supply superimposing unit 17 transmits the signal on which the voltage is superimposed to the terminal 18 of the Ethernet work. According to this embodiment, it is possible to provide a power supply system in which the reliability of the backbone transmission system is ensured and the Ethernet power supply power supply unit and the power supply unit of the main part of the transmission apparatus are shared.

  FIG. 3 is a block diagram showing the main part of the second embodiment of the present invention. The same components as those in FIG. 1 are denoted by the same reference numerals. In this embodiment, for example, a failure or the like occurs on the downstream ether power supply side, and an ether power supply current / current that detects that a current higher than a specified value flows on the ether cable or in the terminal 18 via the cable is detected. A voltage monitoring unit and a power supply switch for turning off power supply to the port where the fault has occurred are configured. An abnormality detection set value (a reference value for determining abnormality in power, current, and voltage) is set in the ether power supply power calculation means 8.

  As shown in the figure, the operation will be described with a circuit for one port. The -48V power supply is supplied to the e-support via the FET of the power supply switch 10. The ether power supply calculating means 8 calculates the power value supplied to the e-support and considers power higher than the set power value as abnormal when consumed by the terminal (cable.

  Further, the feeding current / voltage is monitored by the ammeter 11 and the voltmeter 12, respectively, and when the feeding current is larger than the set current value or when the feeding voltage is lower than the set voltage, it is regarded as abnormal. In the event of an abnormality, the power supply switch 10 immediately performs a cutoff control on the corresponding port by the Ethernet power supply control circuit 13 so that the main transmission device main part 15 is not affected. Further, recovery from an abnormal state is performed when no abnormality is detected during a certain protection time Tp period.

  According to this embodiment, when an abnormality in the Ethernet power supply system is detected, the power supply switch 10 of the corresponding Ethernet power supply circuit can be shut off (off) so that other devices are not affected.

FIG. 4 is a block diagram showing the main part of the third embodiment of the present invention. The same components as those in FIG. 1 are denoted by the same reference numerals. When distributing the power Pe allocated to the ether power supply, the current / voltage monitoring condition is set for each port based on the value calculated by Pe / n so as to be equal to the number of connected terminals n. ing. In FIG. 4, only 81 to 8n Ethernet supply power calculation means are provided. Then, abnormality detection set values (power, current, voltage) can be set in common in each of the ether power supply power calculation means 81 to 8n. Each Ethernet power supply calculation means 81 to 8n compares the set value with the actual power consumption, and monitors the voltage value and the current value. The power Pn supplied to each Ethernet power supply port is Pn = Pe / n
It is represented by For n ports to which the terminal 18 is connected, the value calculated by Pe / n is used as the power threshold value at each port. When an abnormal current is detected in any of the ports, a control signal is input from the corresponding Ethernet power supply calculation means 8i (i = 1 to n) to the Ethernet power supply control circuit 13, and the Ethernet power supply control circuit 13 The power supply switch 10 of the port in which is detected is cut off.

According to this embodiment, power can be evenly distributed to each Ethernet power feeding circuit by the Ethernet power feeding circuit.
FIG. 5 is a block diagram showing the main part of the fourth embodiment of the present invention. The same components as those in FIG. 4 are denoted by the same reference numerals. When distributing the power Pe allocated to the ether power supply, current / voltage monitoring conditions are set for each port based on the power consumption Pi (i = 1 to n) required by the terminal 18 connected in advance. Although a threshold can be set for each ether support, the threshold is set for each ether power supply circuit 9 at the time of setting in order to keep the condition of Pe> ΣPi. Then, setting restrictions are applied so that the sum of the power limit values does not exceed Pe.

  According to this embodiment, sufficient power can be used in each power supply circuit by distributing the power that can be supplied to each Ethernet power supply circuit according to the maximum power value assigned to the Ethernet power supply circuit.

  FIG. 6 is a block diagram showing the main part of the fifth embodiment of the present invention. The same components as those in FIG. 5 are denoted by the same reference numerals. In this embodiment, the power limit value for each ether support is arbitrary. However, when the sum of the power limit values exceeds Pe, the ether power supply is shut off from the port with the lower priority according to the priority information, and Pe> ΣPi It is automatically controlled so that

  When the total power Pe allocated to the ether power supply calculated in the first embodiment is exceeded, the current / voltage monitoring conditions set in the third and fourth embodiments are exceeded ( Except in the case of the abnormal current in the second embodiment, the power supply switch supplies the Ethernet power supply of the low-priority port according to the priority information set for each port, except in the case of the abnormal current in the second embodiment. 10 means.

  The power supply control request according to the power supply state and condition of each port is sent to the Ethernet power supply control circuit 13. Here, the port priority information is introduced, and the power consumption of the backbone transmission apparatus can be secured by sequentially cutting off the power supply from the port with the lower priority in order to keep the condition of Pe> ΣPi.

  According to this embodiment, priority can be assigned to the Ether power supply circuit, and power can be distributed from the Ethernet power supply circuit having a higher priority according to the priority information, whereby preferable power distribution can be performed.

  FIG. 7 is a block diagram showing a sixth embodiment of the present invention. The same components as those in FIG. 1 are denoted by the same reference numerals. In the figure, 1 is a power source, 3a is a voltmeter, 20 is a small resistance, 4 is a voltmeter, 5 is a temperature sensor, 6 is a total supply power calculation means, 7 is a power supply circuit, 8 is an ether power supply calculation means, 9 Is an Ethernet power supply circuit, 10 is a power supply switch, 11a is a voltmeter, 21 is a small resistor connected to both ends of the voltmeter 11a, 12 is a voltmeter, 19 is a multiplier that multiplies voltage and current, and 13 is an Ethernet power supply. The control circuit, 14 is an Ethernet power supply circuit, 15 is a main transmission apparatus main part, 16 is a basic transmission line, 17 is an Ethernet power supply superimposing unit, and 18 is an Ethernet power supply system terminal.

  Both the voltmeters 3a and 11a measure voltage drops generated at both ends of a small resistor and obtain them as current values. An ammeter 2, a voltmeter 3 a, a voltmeter 4, and a temperature sensor 5 are connected to the total supply power calculation means 6. Further, in the total supply power calculation means 6, the basic transmission apparatus side setting monitoring information is set. As the information, a power monitoring lower limit value, a current lower limit value, and a voltage lower limit value are set. As the voltmeters 3a, 4, 11a, and 12, A / D converters that convert measured analog voltages into digital signals are used. In addition, power supply setting monitoring information (power monitoring upper limit value, current upper limit value, voltage lower limit value) is set in the Ether power supply power calculation means 8. The main transmission apparatus main part 15 and the Ether power supply control circuit 13 exchange power supply priority information. The operation of the system configured as described above will be described as follows.

  A -48V power source is generated from the AC 100V by the power source 1 and used as a common power source for the main transmission apparatus main part (main signal processing part and control / monitoring processing part) 15 and the Ethernet power supply system. That is, V1 to Vn are generated from the power supply circuit 7 of the main transmission apparatus main part 15 and supplied to the devices in the block. The Ethernet power supply circuit 14 generates a voltage Vm as a power supply for the Ethernet power supply system.

  The total supply power calculation means 6 obtains the current in-apparatus temperature from the temperature sensor 5, assigns derating information of the -48V generated power supply, and calculates the -48V power supply capability. Here, for the derating characteristic, a look-up table referenced from temperature information can also be used. Here, the power supply state to the main transmission apparatus main part 15 and the Ethernet power supply system is monitored, and the maximum power consumption is monitored. This is because the main transmission device main unit 15 must always ensure the maximum power consumption for changing the power consumption depending on the frequency of the main signal or the control monitoring process. For this reason, the initial value of the power secured by the main transmission apparatus main unit 15 at the time of starting the apparatus is input to the total supply power calculating means 6. This initial value is determined in advance by experiments or the like.

  The voltage and current of the -48V power supply are measured in order to calculate the power consumption. Although it is nominally −48V, some voltage fluctuation occurs, and some voltage drop occurs in FET, small resistance, wiring, and the like. From this -48V power supply, OBP (on-board power supply) that generates the necessary voltage in the internal device generally has a characteristic that the input current increases when the input voltage decreases (constant power). It is more accurate to think. Here, since the current / voltage of the -48V power supply is monitored, it is possible to monitor whether each is a normal value. Here, the current lower limit value and the voltage lower limit value are monitored (alarm alarm at the time of abnormality).

  The difference between the -48V power supply total supply capability obtained in this way and the power (maximum value) secured in the main transmission apparatus main part 15 is the amount that can be distributed as the Ether power supply Pe. There are several ways how to further allocate this ether powered power to each ether support. This is performed by the Ether power supply calculating means 8. The power value for each Ethernet power supply port by the multiplier 19 is input to the Ethernet power supply power calculation means 8. Each method has already been described with reference to FIGS.

  Here, assuming that the ether power distribution based on the priority information is performed, a circuit for monitoring the supply voltage and the supply current is provided for each ether support (voltmeter 11a, 12), and there is a failure on the terminal (cable) side. Monitoring is performed to prevent abnormal power supply from occurring. Moreover, the electric power value currently supplied is calculated and calculated | required, and supply more than the value preset as an electric power value is monitored. If any of the feed current / voltage / power value is abnormal, the feed switch 10 is cut off according to the embodiment of FIG. Except for the port where the abnormality has occurred, the port to which Ethernet power feeding is performed is determined again based on the power feeding power setting value and priority information of the port to which the terminal 18 is connected. By these operations, it is possible to realize common power supply that performs Ethernet power supply while securing power to the main transmission device main unit 15.

  Conventionally, it can be utilized for downsizing / high efficiency of a backbone transmission apparatus in which an Ether power supply system power supply is separated and independent.

1 is a block diagram illustrating a first exemplary embodiment of the present invention. It is a figure which shows the example of an output current characteristic. It is a block diagram which shows the principal part of the 2nd Example of this invention. It is a block diagram which shows the principal part of the 3rd Example of this invention. It is a block diagram which shows the principal part of the 4th Example of this invention. It is a block diagram which shows the principal part of the 5th Example of this invention. It is a block diagram which shows the 6th Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Power source 3 Ammeter 4 Voltmeter 5 Temperature sensor 6 Total supply power calculation means 7 Power supply circuit 8 Ether power supply calculation means 9 Ether power supply circuit 10 Feed switch 11 Ammeter 12 Voltmeter 13 Ether power supply control circuit 14 Ether power supply circuit 15 Main transmission equipment main part 16 Basic transmission line 17 Ether feeding superposition part 18 Terminal

Claims (5)

One power source,
At least one power supply circuit for supplying power to the main part of the backbone transmission device from the power source;
The total supply power Po is calculated from the ambient temperature of the power source, and the supply power Pt to the main transmission apparatus main part is calculated from the voltage of the power source and the current to the main transmission apparatus main part. Calculation means;
At least one Ethernet power supply circuit receiving power from the power source;
The total power supply Po is subtracted from the power Pt to be supplied to the main part of the backbone transmission device, and the ether power supply calculated from the voltage and current of the Ethernet power supply circuit is compared. Ether power supply calculating means for outputting a control signal for turning on / off the Ethernet power supply circuit to the Ethernet power supply control circuit ;
A power supply switch for turning on / off the Ethernet power supply circuit that supplies the network from the power source;
An ether power supply control circuit for controlling on / off of the power supply switch in response to a control signal from the ether power supply calculating means;
A power supply system consisting of.   2. The power supply system according to claim 1, wherein, when detecting an abnormal current, the Ethernet power supply control circuit shuts off a power supply switch of the corresponding Ethernet power supply circuit. 3.   The power supply system according to claim 2, wherein the Ethernet power supply control circuit equally distributes the power that can be supplied to the Ethernet power supply circuit for each Ethernet power supply circuit.   3. The power supply system according to claim 2, wherein power that can be supplied to the Ethernet power supply circuit is distributed according to a maximum power value assigned to each Ethernet power supply circuit.   When the power that can be supplied to the Ethernet power supply circuit is distributed according to the demand of each Ethernet power supply circuit, it is distributed from the Ethernet power supply circuit having a high priority according to the priority information attached to each Ethernet power supply circuit. The power supply system according to claim 3 or 4.

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