JP6578602B2 - Power supply system - Google Patents

Description

  The present invention relates to a power supply system suitable for consuming surplus power.

  Conventionally, in the submarine cable communication system, a relay device that regenerates or amplifies a communication signal is mounted on each of a number of submarine devices, and these submarine devices are connected in a chain with a submarine cable, and this is connected to a seabed that spreads between two points on land. The technology to lay in is known. A power line is mounted on such a submarine cable, and a power supply circuit provided in each submarine device is connected in series to the power line. Then, a constant DC current (DC constant current) is transmitted to the power line from land power supply devices disposed at both ends of the land, and each submarine device uses the voltage drop of the DC constant current as power. It is configured as follows.

However, in the submarine cable communication system as described above, a constant amount of power can be distributed to all submarine devices connected to the submarine cable by allocating the amount of power to be consumed to each submarine device. It was configured as follows.
For this reason, in the conventional submarine device, all the power that should be consumed by the observation device when the power is not supplied to the observation device even though the submarine device is in a power supplyable state. Needed to be consumed. That is, of the power allocated to one submarine device, surplus power that is no longer consumed in the non-powered observation device (not in the power supply state) is consumed in the pseudo load device.

As an example of the power supply system having such a configuration, the inventions described in Patent Documents 1 and 2 are known.
In patent document 1, it aims at the receiving power by the side of an input not changing with respect to the load fluctuation of an output. The first circuit receives a DC constant current at the primary input port, detects the voltage of the secondary port as an output, and the first switching on the primary side so that the first voltage detection value becomes a constant value. A constant DC voltage is output to the secondary port by controlling the circuit. The second circuit receives the DC constant voltage output of the secondary port of the first circuit, converts it to a constant current by the constant current circuit, and supplies the constant current to the external load connected to the tertiary port as the final stage output To do. The third circuit receives the voltage generated on the primary side of the first circuit as the primary side input voltage, detects the primary side voltage, and is on the primary side so that the second voltage detection value becomes a constant value. A balanced DC constant current input / DC constant current distribution output device configured to supply power to a constant resistance load connected to the secondary side by controlling a second switching circuit is disclosed.

  Patent Document 2 aims to prevent constant current feeding even if there is a large fluctuation in power consumption. In a submarine cable system of a constant current feeding system, a switching circuit connected in series to a constant current line and converting the constant current into a rectangular wave current, a transformer converting a rectangular wave current into another rectangular wave current, A rectifier circuit that rectifies the output, and a high-voltage constant current is insulated by a switching circuit, a transformer, and a rectifier circuit, and is electrically separated from the load side. A power circuit for a submarine cable system is disclosed in which a Zener diode is connected to an output of a rectifier circuit, and a low-voltage side voltage separated by a transformer and rectified by the rectifier circuit is absorbed by a Zener diode. Yes.

Patent No. 5176152 JP-A-11-150492

As described above, in Patent Document 1, the voltage generated on the primary side of the first circuit is received as the primary side input voltage, and the second voltage detection value that is the detection value of the primary side voltage is set to a constant value. By configuring the third circuit to supply power to the constant resistance load connected to the secondary side of the second switching circuit by controlling the second switching circuit on the primary side so that The surplus power that is no longer consumed by the device (not in the power supply state) is consumed in the constant resistance load.
However, in Patent Document 1, a space for mounting the third circuit is required due to an increase in the number of parts constituting the third circuit and an increase in complexity.
Further, in the conventional submarine device, the surplus power that is no longer consumed in the non-powered observation device among the power allocated to one submarine device as described above is consumed in the pseudo load device. At this time, feedback control is performed between the DC power converter for supplying power to the observation device and the pseudo load device, so that the power balance between the DC power converter and the pseudo load device is optimally stabilized. It was controlled to hold at the point.
However, in order to perform feedback control between the DC power converter and the pseudo load device, the circuit configurations of both devices are complicated.

Furthermore, the pseudo load device can be realized by using a Zener diode, but when it is used at high power and high voltage, it is necessary to make a multi-stage connection, and the multi-stage connection has a problem in stability and reliability due to characteristic variations of each element. Become.
In detail, a Zener diode is a semiconductor element formed by pn junction of a semiconductor. Actually, the characteristics of commercially available Zener diodes vary by about 5% to 10% due to manufacturing errors and the like. A high-precision type with little variation in characteristics exists, but is extremely expensive.
As in this case, when a large number of stages are connected to consume large power and high voltage, it is difficult to obtain the expected characteristics due to the accumulation of element characteristic variations. Note that high-precision Zener diodes that are connected in multiple stages lead to high costs.
In general, in a Zener diode, when a current starts to flow, its constant voltage characteristic is distorted and begins to collapse. For example, paragraph [0035] of Patent Document 2 describes an example in which a current of 8 A is passed through a Zener diode, but has a drawback of poor voltage stability.
For this reason, it has been desired to provide a pseudo load device having a simple configuration capable of consuming surplus power that is no longer consumed in the observation device (non-powered state).
The present invention has been made in view of the above, and an object thereof is to provide a power supply system that can consume surplus power that is no longer consumed with a simple configuration.

In order to solve the above problem, the invention according to claim 1 is a parent device having a power supply unit and a control unit, a child device connected from the parent device via a cable, and the child device connected to the child device A DC power conversion unit including a pseudo load device, wherein the slave device converts first DC power supplied to the primary side into second DC power and outputs the second DC power to the secondary side. And a power distribution unit that distributes to at least one device, wherein the pseudo load device includes n stages (n is a natural number of 2 or more ) of pseudo load units, and each stage of the pseudo load unit has a terminal An inter-voltage monitoring unit, a control voltage amplifying unit, and a power consuming unit, wherein the inter-terminal voltage monitoring unit, the control voltage amplifying unit, and the power consuming unit are connected in parallel between both terminals of the pseudo load unit. The terminal voltage monitor is connected to the pseudo It is composed of a semiconductor used for monitoring the voltage applied between both terminals of the load unit, and a passive component attached to the semiconductor, and generates a control voltage for making the voltage between the terminals constant. The control voltage amplifying unit amplifies the control voltage and transmits the amplified voltage to the power consuming unit, and the power consuming unit includes a power semiconductor, The pseudo load device is configured to consume power so that a voltage between the terminals is constant by flowing a required current through the power semiconductor in accordance with the control voltage amplified by a voltage amplification unit. It is connected to the primary or secondary side of the DC power converter unit, characterized in Tei Rukoto.

  According to the present invention, it is possible to provide a power supply system capable of consuming surplus power that is no longer consumed with a simple configuration.

It is a block diagram for demonstrating the schematic structure of the electric power supply system which concerns on 1st Embodiment of this invention. It is a block diagram for demonstrating the structure of the submarine apparatus with which the electric power supply system which concerns on 1st Embodiment of this invention was equipped. It is a block diagram for demonstrating the more detailed connection relation of the main DC / DC converter and output DC / DC converter which are used in the electric power supply system which concerns on 1st Embodiment of this invention shown in FIG. It is a block diagram showing the pseudo load unit which is 1 unit of the pseudo load apparatus used for the electric power supply system which concerns on 1st Embodiment of this invention. The graph about the voltage-time-current showing the operation | movement at the time of inputting into the pseudo load unit which is 1 unit of the pseudo load apparatus used for the power supply system which concerns on 1st Embodiment of this invention, changing input voltage. FIG. It is a graph about the voltage-time-current showing the operation | movement at the time of giving a load fluctuation | variation with respect to the pseudo load unit which is 1 unit of the pseudo load apparatus used for the electric power supply system which concerns on 1st Embodiment of this invention. . (A)-(f) is a sequence diagram (the 1) for demonstrating the starting operation | movement of each apparatus with which the electric power supply system which concerns on 1st Embodiment of this invention was equipped. (A)-(g) is a sequence diagram (the 2) for demonstrating the starting operation | movement of each apparatus with which the power supply system which concerns on 1st Embodiment of this invention was equipped. It is a block diagram showing the pseudo load unit which is 1 unit of the pseudo load apparatus used for the electric power supply system which concerns on 2nd Embodiment of this invention. It is a block diagram showing the pseudo load unit which is 1 unit of the pseudo load apparatus used for the electric power supply system which concerns on 3rd Embodiment of this invention. It is a block diagram for demonstrating the structure of the submarine apparatus with which the electric power supply system which concerns on 4th Embodiment of this invention was equipped. It is a block diagram for demonstrating the more detailed connection relation of the main DC / DC converter and output DC / DC converter which are used in the electric power supply system which concerns on 4th Embodiment of this invention shown in FIG.

Hereinafter, the present invention will be described in detail with reference to embodiments shown in the drawings.
The present invention has the following configuration in order to provide a power supply system that can consume surplus power that is no longer consumed with a simple configuration.
That is, the power supply system of the present invention is a power supply system including a parent device having a power supply unit and a control unit, and a child device connected via a cable from the parent device, A DC power converter that converts the first DC power supplied to the primary side into second DC power and outputs it to the secondary side, and the power that distributes the second DC power to the pseudo load device and at least one device The surplus power of the first DC power or the second DC power is connected to the distribution unit and the primary side or the secondary side of the DC power conversion unit according to the increase or decrease of the number of devices connected to the power distribution unit. And a pseudo load unit that consumes.
By providing the above configuration, it is possible to provide a power supply system that can consume surplus power that is no longer consumed with a simple configuration.
Hereinafter, the features of the present invention will be described in detail with reference to the drawings.

Embodiments of the present invention will be described with reference to the drawings.
<First Embodiment>
<Configuration of power supply system>
FIG. 1 is a block diagram for explaining a schematic configuration of a power supply system 1 according to the first embodiment of the present invention.
As shown in FIG. 1, the power supply system 1 includes a land control device 2, a land power supply device 10, submarine cables 16-1 to 16-4, and submarine devices 20-1 to 20-3.
In the power supply system 1, a submarine cable 16-1 in which a control cable 4 extending from a land control device 2 arranged on land and a power line 12 extending from a land power supply device 10 is bundled is connected to one end of the submarine device 20-1. Has been. Further, each of the submarine cables 16-1 to 16-4 is connected in series so that the submarine devices 20-1 to 20-3 are interposed therebetween. Finally, the submarine device 20-3 is connected to the submarine cable 16-4. Is connected to the sea earth 22-4 through the power line 12-4 accommodated in the power source.

As shown in FIG. 1, the power supply system 1 includes a submarine device in which a land power supply device 10 is electrically grounded to a ground 11 on the land side, and is disposed on the farthest seabed from the land side. In 20-3, the power line 12-4 accommodated in the submarine cable 16-4 is grounded to the sea earth 22-4, thereby forming a closed circuit in power supply.
The submarine devices 20-1 to 20-3 provided in the power supply system 1 are connected to the functional sea earth 22-1 to 22-3 via resistors, respectively, so that the submarine devices 20-1 to 20-1 are connected. It plays the role which stabilizes the electric power feeding path potential to the observation apparatus (not shown) connected to each of 20-3.

The land control device 2 constitutes control means, and outputs control data to each submarine device via the control cable 4.
Further, the land control device 2 includes a transmission unit 2 a that transmits control data for performing various controls such as switching the power supply path path relay 62 to the transmission unit 40 provided in the undersea device 20.
The land power supply apparatus 10 is a DC power supply apparatus that constitutes a power supply means and generates a DC constant current having a negative polarity, for example.
In the present embodiment, the parent apparatus is configured by including the land power supply apparatus 10 (power supply means) and the land control apparatus 2 (control means).
The submarine cable 16 includes a control cable 4 that includes a plurality of optical fibers that transmit light of different wavelengths and carries control data, and a power line 12 that carries power.
The submarine device 20 constitutes a child device and is usually called a junction box in order to connect an observation device such as a seismometer installed on the seabed, and is connected to the submarine cable 16 from the land power supply device 10 or another submarine device 20. The electric power supplied via the observation device is distributed and supplied to the observation device, and the observation data observed by the observation device is transmitted to the land control device 2 via the submarine cable 16.
In the present embodiment, the power supply system 1 will be described assuming that, for example, three seabed devices 20 are arranged on the seabed. However, the number of the seabed devices 20 is not limited in the present invention.

<Configuration of submarine device>
FIG. 2 is a block diagram for explaining the configuration of the submarine device 20 provided in the power supply system 1 according to the first embodiment of the present invention.
The submarine device 20-1 shown in FIG. 1 is connected between the submarine cable 16-1 and the submarine cable 16-2, but the other submarine devices 20-2 and 20-3 are also two different submarine cables. In order to simplify the description, the description will be made using only the names and symbols of the submarine device 20, the submarine cable 16, and the functional sea earth 22. For this reason, in FIG. 2, it is assumed that the submarine cable 16 on the left side of the drawing is laid toward the land side.
2 includes a transmission unit 40, a drive power supply unit 50, a power reception unit 60, a control unit 70, and an output unit 80.
Between the power receiving unit 60 and the control unit 70, main DC / DC converters 64 and 66, whose primary sides are connected in series, are provided.
The submarine device 20 is provided with a submerged / detachable connector 30a, 30b for connecting each submarine cable 16 in the housing 20a. The power supply path 32 a, the power supply path 32 b, the primary winding of the main DC / DC converter 64 and the main DC / DC converter 66 are connected to the primary winding provided in the transformer of the main DC / DC converter 64. The power line 32c is connected to the primary winding of the power supply path 32c, the power supply path 32d is connected to the primary winding of the main DC / DC converter 66, and the drive power supply section 50 is connected to the power supply section 60d. The distribution line connected to the power supply path 32e, and the distribution line connected to the underwater detachable connector 30b from the drive power supply unit 50 is referred to as the power supply path 32f.

The transmission unit 40 receives control data from the land control device 2 via the control cable 4 of the submarine cable 16.
The drive power supply unit 50 includes a DC / DC converter 52 and switches the contact state of the power supply path path relay 62 based on the control data received by the transmission unit 40. The drive power supply unit 50 includes a low voltage circuit connected in series between the power supply paths 32e and 32f, for example, a Zener diode ZD1, and a DC / DC converter 52 using a Zener voltage generated between the anode and the cathode of the Zener diode ZD1. Is operated to generate drive power, and based on the control data received by the transmission unit 40, power is supplied to a solenoid coil provided in the power supply path path relay 62 described later, thereby closing the contact of the power supply path path relay 62. Switch from state to open state.

The power receiving unit 60 includes a power supply path path relay 62 that is connected between the power supply paths 32a and 32e and passes between the power supply paths 32a and 32e.
The power receiving unit 60 includes a primary winding of the transformer of the main DC / DC converter 64 and a primary winding of the transformer of the main DC / DC converter 66.
The main DC / DC converter 64 includes a switch SW65 connected between the power supply paths 32b and 32c, a primary winding of a transformer connected between the power supply paths 32b and 32c, a switching element (not shown), A secondary winding facing the primary winding and a rectifying / smoothing circuit (not shown) connected to the subsequent stage of the secondary winding are included.
The main DC / DC converter 66 includes a switch SW67 connected between the power supply paths 32c and 32d, a primary winding of a transformer connected between the power supply paths 32c and 32d, a switching element (not shown), And a secondary winding facing the primary winding.
The switches SW65 and 67 are so-called break relays, and are configured such that the contacts are opened when a current is passed through the solenoid coil. By switching the switches SW65 and 67 based on the control data received by the transmission unit 40, the power supply to the secondary side of the main DC / DC converters 66 and 67 can be increased or decreased.

The main DC / DC converters 66 and 67 constitute a direct current power converter, and play a role of converting the first direct current power supplied to the primary side into the second direct current power and outputting it to the secondary side. The control unit 70 constitutes a power distribution unit and plays a role of distributing the second DC power to the observation devices 100-1 to 100-4 (devices).
The control unit 70 includes a secondary winding facing the primary winding of the transformer of the main DC / DC converter 64, a secondary winding facing the primary winding of the transformer of the main DC / DC converter 66, and an output. Primary windings of transformers for the DC / DC converters 72-1 to 72-4.
The output DC / DC converters 72-1 to 72-4 include a primary winding of a transformer connected to the secondary side of the main DC / DC converters 64 and 66, a switching element (not shown), and the primary. A secondary winding facing the winding and a rectifying / smoothing circuit (not shown) connected to a subsequent stage of the secondary winding are included.
The output DC / DC converters 72-1 to 72-4 can set their respective operations to the ON / OFF state based on the control data received by the transmission unit 40.

Furthermore, the control unit 70 outputs output ports Pr1 and Pr2 that output surplus power to the pseudo load device 90 from the DC power supplied from the secondary side of the main DC / DC converters 64 and 66, a functional earth terminal G, It has.
By electrically grounding the functional earth terminal G of the control unit 70 which is electrically insulated and kept in a floating state to the functional sea earth 22 via the resistor R1, the potential of the power supply path to the observation devices 100-1 to 100-4 Can be stabilized.
The output unit 80 includes output ports P1 to P4 that output DC power supplied from the secondary sides of the output DC / DC converters 72-1 to 72-4, respectively.
Observation devices 100-1 to 100-4 arranged on the seabed are connected to the output ports P1 to P4 as necessary, and power is consumed in each of the observation devices 100-1 to 100-4. .
As shown in FIG. 2, the transmission unit 40 and the control unit 70 are connected via a cable 42, and control data is output from the transmission unit 40 to the control unit 70 via the cable 42.

<Control data>
Here, the control data transmitted from the land control device 2 to the submarine device 20 via the control cable 4 will be described.
As the format of the device address unique to each of the submarine devices 20-1 to 20-3 shown in FIG. 1, for example, # 001 to # 003 may be used, and in addition to this, control data for specifying the power supply state of the device D0, control data D1 for designating the ON / OFF state of the switch SW65, control data D2 for designating the ON / OFF state of the switch SW67, DC / DC for output that outputs power to each of the observation devices 100-1 to 100-4 Designate each of control data D3 to D6 for designating ON / OFF states of operations of DC converters 72-1 to 72-4.
In the control data D0 to D2, “1” represents the ON state (closed state) and “0” represents the OFF state (open state) for the contact state of each relay. The control data D3 to D6 indicate that “1” represents an ON state (operation state) and “0” represents an OFF state (stop state) for the operation / stop state of each output DC / DC converter. To do.

  The data example shown in Table 1 indicates that all the output DC / DC converters 72-1 to 72-4 of the submarine devices 20-1 to 20-3 are in an operating state.

  FIG. 3 shows a combination of the main DC / DC converters 64 and 66 and the output DC / DC converters 72-1 to 72-4 shown in FIG. 2 used in the power supply system 1 according to the first embodiment of the present invention. It is a block diagram for demonstrating a detailed connection relationship.

<Main DC / DC converter>
The primary sides of the main DC / DC converters 64 and 66 are connected in series to the power supply paths 32b and 32d via the power supply path 32c. On the other hand, the secondary sides of the main DC / DC converters 64 and 66 are connected in parallel to the terminals O1 and O2.
On the primary side of the main DC / DC converter 64, the switch SW65 and the converter 64i are connected in parallel, and the converter 64i is connected in parallel to the primary winding of the transformer 64t. When the switch SW65 is in an open state, the converter 64i converts the DC voltage input as the first DC power from the power supply paths 32b and 32c into high frequency power by using a switching element (not shown), thereby converting the DC voltage to high frequency power. And output to the primary winding of the transformer 64t.

On the secondary side of the main DC / DC converter 64, a rectifying / smoothing circuit 64c is connected in parallel to the secondary winding of the transformer 64t. The rectifying / smoothing circuit 64c is a high-frequency power induced in the secondary winding of the transformer 64t. Is rectified and smoothed by a diode and a capacitor to generate a DC voltage, and the DC voltage is output to the terminal O1 as the second DC power via the diode Di1.
The main DC / DC converter 66 has the same configuration as the main DC / DC converter 64, and a description thereof will be omitted.
The diodes Di1 and Di2 provided in the main DC / DC converters 64 and 66 are connected from the main DC / DC converter to the other main DC / DC when the secondary side is connected in parallel to the terminals O1 and O2. It is provided to prevent the output current from flowing into the converter. The outputs of the main DC / DC converters 64 and 66 can be connected in parallel by interposing the diodes Di1 and Di2.

As described above, the secondary sides of the main DC / DC converters 64 and 66 are connected to the terminals O1 and O2 in parallel to each other. As shown in FIG. 3, the terminal O1 is connected to the terminal I1, and the terminal O2 is It is connected to the terminal I2.
The primary sides of the output DC / DC converters 72-1 to 72-4 are connected in parallel to the terminals I1 and I2, and the secondary sides of the output DC / DC converters 72-1 to 72-4 are connected to each other. Are independently connected to the output ports P1 to P4. Note that the observation devices 100-1 to 100-4 can be detachably connected to the output ports P1 to P4 as necessary.
As described above, the secondary sides of the main DC / DC converters 64 and 66 are connected to the terminals O1 and O2 in parallel with each other, and the output DC / DC converters 72-1 to 72-1 are connected to the terminals O1 and O2 via the terminals I1 and I2. Distributing the second DC power converted by the main DC / DC converters 64 and 66 to the output DC / DC converters 72-1 to 72-4 by connecting the primary sides of 72-4 in parallel with each other. Is possible.
The operations of the converter and the rectifying / smoothing circuit provided in each of the output DC / DC converters 72-1 to 72-4 are the same as those of the converter 64i and the converter 64c of the main DC / DC converter 64, and thus description thereof is omitted. To do.
The terminals O2 and I2 are connected to a functional earth terminal G (FIG. 2) provided in the control unit 70. As shown in FIG. 2, the functional earth terminal G is connected to the functional sea earth 22 via a resistor R1. It is connected.

The pseudo load device 90 shown in FIG. 3 is configured by connecting n pseudo load units 92-1 to 92-n in series.
The pseudo load device 90 can configure a pseudo load device corresponding to a load voltage of 400 V, for example, by connecting 50 pseudo load units each having a load voltage of 8 V in series.

FIG. 4 is a block diagram showing a pseudo load unit which is one unit of the pseudo load device 90 used in the power supply system 1 according to the first embodiment of the present invention.
As shown in FIG. 4, the terminal A of the pseudo load unit 92-k is connected to the terminal B of the pseudo load unit 92- (k-1), and the terminal B of the pseudo load unit 92-k is connected to the pseudo load unit 92- ( k + 1) to terminal A.
The pseudo load unit 92-k includes a terminal voltage monitoring unit 94, a control voltage amplification unit 96, and a power consumption unit 98, and each unit is connected in parallel between the terminals A and B.
The inter-terminal voltage monitoring unit 94 includes a semiconductor (hereinafter referred to as a semiconductor) used for monitoring the voltage V _AB applied between the terminals A and B, and a passive component associated therewith, and is connected between the terminals A and B. The voltage V _AB is monitored, and the amount of current flowing through the semiconductor is adjusted so that the voltage V _AB between the terminals A and B is constant without depending on the current Id flowing through the power consumption unit 98.

The inter-terminal voltage monitoring unit 94 generates a control voltage Vs by the current flowing through the semiconductor, and transmits this to the control voltage amplifying unit 96. The inter-terminal voltage monitoring unit 94 adjusts the level of the control voltage Vs transmitted to the control voltage amplifying unit 96 by changing the amount of current flowing through the semiconductor so that the voltage between the terminals A and B is constant.
The control voltage amplifying unit 96 includes a signal amplifying semiconductor used for signal amplification and a passive component associated with the signal amplification, and the control voltage Vs generated by the inter-terminal voltage monitoring unit 94 is multiplied by g (g> The control voltage g × Vs is amplified to 1) and transmitted to the power consumption unit 98.
The power consuming unit 98 is composed of a power semiconductor, and a required current Id is supplied to the power semiconductor in accordance with the control voltage g × Vs amplified by the control voltage amplifying unit 96. To consume. The power semiconductor provided in the power consumption unit 98 may be any one of a power transistor, a field effect transistor, and an IGBT (Insulated Gate Bipolar Transistor).
Moreover, it is preferable to attach a heat sink for dissipating the heat generated by the power consumption to the power semiconductor.

Next, the operation of the pseudo load unit 92-k shown in FIG. 4 will be described.
The inter-terminal voltage monitoring unit 94 monitors the voltage V _AB applied between the terminals A and B, generates a control voltage Vs by a current flowing through the semiconductor, transmits the control voltage Vs to the control voltage amplifying unit 96, and The level of the control voltage Vs transmitted to the control voltage amplifier 96 is adjusted by changing the amount of current flowing through the semiconductor so that the voltage V _AB between A and B is constant.
The control voltage amplification unit 96 amplifies the control voltage Vs generated by the inter-terminal voltage monitoring unit 94 by a factor of g and transmits the control voltage g × Vs to the power consumption unit 98.
The power consumption unit 98 causes the power semiconductor to consume power by flowing a required current Id to the power semiconductor in accordance with the control voltage g × Vs amplified by the control voltage amplification unit 96.

FIG. 5 shows the voltage V applied between the terminals A and B with respect to the pseudo load unit 92-k which is one unit of the pseudo load device 90 used in the power supply system 1 according to the first embodiment of the present invention. It is a graph about the voltage-time-current showing the operation | movement at the time of inputting, changing _AB .
The voltage on the vertical axis (left side) shown in FIG. 5 represents the voltage V _AB input between the terminals _AB of the pseudo load unit 92-k shown in FIG. 4, and the voltage on the vertical axis (right side) shown in FIG. The current represents the current Id flowing through the power semiconductor provided in the power consuming unit 98, and is based on the potential at the point B (0V level) shown in FIG.
In the range from time t1 to t2 and in the range where the voltage waveform of the voltage V _AB applied between the terminals A and B gradually increases from 0V to 7.7V (<g × Vs), the power consumption unit 98 is provided. The current waveform of the current Id flowing through the power semiconductor is 0.0 A.
At this time, when the control voltage g × Vs for controlling the power semiconductor is less than 7.7 V, the current Id remains at 0.0 A because the power semiconductor is off.
Next, in the range from time t2 to t3 and in the range where the voltage waveform of the voltage V _AB applied between the terminals A and B rises to 7.7 V (> g × Vs) or more, the power consumption unit 98 is provided. Although the current waveform of the current Id flowing through the power semiconductor is steeply increased to about 0.0 A to 3.4 A, the voltage waveform of the voltage V _AB applied between the terminals A and B is almost constant. 7V (> g × Vs).
At this time, since the control voltage g × Vs for controlling the power semiconductor is 7.7 V or more, the power semiconductor is turned on, so that the current Id is 0.0 A˜ in accordance with the control voltage g × Vs. It rises steeply to about 3.4A.
The above-described control voltage g × Vs may be appropriately designed according to the type of power semiconductor.

FIG. 6 shows a voltage − representing an operation when a load change is applied to the pseudo load unit 92-k which is one unit of the pseudo load device 90 used in the power supply system 1 according to the first embodiment of the present invention. It is a graph figure about time-current.
The voltage on the vertical axis (left side) shown in FIG. 6 represents the voltage V _AB input between the terminals _AB of the pseudo load unit 92-k shown in FIG. 4, and the voltage on the vertical axis (right side) shown in FIG. The current represents the current Id flowing through the power semiconductor provided in the power consuming unit 98, and is based on the potential at the point B (0V level) shown in FIG.
In the load fluctuation test, a pulsating current having an offset voltage of 7.7 V or more and a frequency of about 4 Hz is applied as a voltage V _AB between the terminals A and B.
At this time, since the control voltage g × Vs for controlling the power semiconductor is 7.7 V or more, the power semiconductor is always in an on state, so that the power voltage is controlled according to the control voltage g × Vs. The current waveform of the current Id flowing through the semiconductor fluctuates between about 2.55 A and about 3.375 A centering on 3.0 A. At this time, the voltage waveform of the voltage V _AB applied between the terminals A and B falls within the range of 7.70V to 7.71V.

<Operation of power supply system>
Next, with reference to FIGS. 7A to 7F and FIGS. 8A to 8G, the start-up operation of each device provided in the power supply system 1 according to the first embodiment of the present invention. explain. FIGS. 7A to 7G and FIGS. 8A to 8G are sequence diagrams for explaining the start-up operation of each device provided in the power supply system 1 according to the first embodiment of the present invention. It is.

<Activation of submarine equipment>
When the power supply system 1 shown in FIG. 1 is started, power is supplied to the land power supply device 10 arranged on the land side, and the submarine devices 20-1 to 20- are connected from the land power supply device 10 through the submarine cable 16-1. 3 is supplied with constant current.
As shown in FIG. 7A, when the land power supply apparatus 10 is activated, the current supplied from the land power supply apparatus 10 rises to 0.0 A to 3.0 A at time t0 to t1, and thereafter, 3 A constant current of 0.0 A is supplied.
For example, in the submarine device 20 shown in FIG. 2, constant current power feeding is performed in the order of the submarine cable 16, the power feeding path 32 a, the power feeding path path relay 62, the power feeding path 32 e, the drive power supply unit 50, the power feeding path 32 f, and the submarine cable 16.
Hereinafter, the operation in the submarine device 20 will be described.
As described above, the drive power supply unit 50 is provided with the DC / DC converter 52 of about 15 W to 30 W. When constant current feeding is performed at time t0, the DC / DC converter 52 is activated. As shown in FIG. 7B, the transmission unit 40 is supplied with a supply voltage of 16 V, for example, at time t0. Then, as shown in FIG. 7C, at time t0 to t1, a current of 0.0 A to 3.0 A is supplied from the DC / DC converter 52 to the transmission unit 40 according to the circuit load.

At time t2 shown in FIG. 7 (d), the land control device 2 controls the power supply path path relay 62 and the switches SW65 and 67 provided in each of the submarine devices 20-1 to 20-3 from the closed state to the open state. Device address and control data (D0 = 0, D1 = 0, D2 = 0) are transmitted from the transmission unit 2a to the submarine devices 20-1 to 20-3 via the submarine cable 16-1.
The transmission unit 40 of the submarine devices 20-1 to 20-3 that has received the device address and the control data from the land control device 2 via the submarine cable 16-1 is when the received device address matches the device address of the device. Then, the control data D0 is output to the power receiving unit 60.
At time t2 shown in FIG. 7D, the power receiving unit 60 generates a path relay ON signal based on the control data D0 = 0 input from the transmission unit 40, and applies it to the solenoid coil provided in the feed path path relay 62. Supply power. Thereby, at the time t2 shown in FIG. 7E, the contact of the power supply path path relay 62 provided in the power receiving unit 60 is switched from the closed state to the open state.

FIG. 7F shows the main DC / DC converters 64 and 66 connected to the power receiving unit 60 and the control unit 70, the output DC / DC converters 72-1 to 72-4, and the current flowing through the pseudo load device 90. This indicates that the amount is 3.0 A, and this current amount is equal to the power supply amount (3.0 A) of the land power supply apparatus 10.
Specifically, the current flowing between the contacts of the feed path path relay 62 in the closed state at time t0 to t2 is shown.
At times t2 to t3, the contacts of the switches SW65 and SW67 of the main DC / DC converters 64 and 66 that are in the non-operating state are switched from the closed state to the open state, and the main DC / DC converter 64 is connected between the power supply paths 32b and 32d. , 66 shows the amount of current that flows through the main DC / DC converters 64, 66 when the power is supplied to switch to the activated state.
At times t3 to t4, the main DC / DC converters 64 and 66 increase the input voltage to about 80% of the input rating, the current resonance circuit starts to be activated, and the switching element is switched at high frequency. The amount of current flowing through the DC / DC converters 64 and 66 is shown.
The amount of current flowing through the pseudo load device 90 and the operating observation device after time t4 is shown.

<Starting of main DC / DC converter>
In FIG. 2, in the power receiving unit 60, when the contact of the power supply path path relay 62 is switched from the closed state to the open state, the power supply paths are connected in series between the power supply paths 32b and 32d at time t2 to t4 shown in FIG. Power supply to the primary windings of the transformers of the main DC / DC converters 64 and 66 and the switching elements (not shown) is started.
At the same time, in FIG. 3, the main DC / DC converter 64 switches the switch SW65 from the closed state to the open state based on the control data D1 = 0 input from the transmission unit 40.
Thereby, the main DC / DC converter 64 is activated. Further, in the main DC / DC converter 64, when the input voltage rises to 400V, which is about 80% of the input rating, at time t3, the current resonance circuit provided in the converter 64i starts to start, and the switching element switches to high frequency. Is done. As a result, the magnetic energy generated in the primary winding induces a voltage in the secondary winding, and a DC voltage is generated by the rectifying and smoothing circuit 64c connected to the subsequent stage of the secondary winding. At times t3 to t5 shown, a DC voltage is output to the output DC / DC converters 72-1 to 72-4.
Similarly to the activation of the main DC / DC converter 64, the main DC / DC converter 66 is also activated.
As a result, at time t5 shown in FIG. 8B, the output voltage 400V is output between the output ports Pr1 and Pr2.

<Operation of pseudo load device>
When the activation of the main DC / DC converters 64 and 66 is completed at time t5 shown in FIG. 8C, an output voltage 400V is output between the output ports Pr1 and Pr2 of the control unit 70, and both terminals of the pseudo load device 90 are output. A voltage of 400 V is applied between them, and a current of 3.40 A flows.
Specifically, for example, since 50 pseudo load units are connected in series to the pseudo load device 90, the voltage V _AB applied between both terminals A and B of one pseudo load unit is 8V (= 400V / 50).
Here, with reference to FIG. 4, the operation | movement by each pseudo load unit provided in the pseudo load apparatus 90 is demonstrated.
In the pseudo load unit, the inter-terminal voltage monitoring unit 94 monitors the voltage V _AB applied between the terminals A and B, generates the control voltage Vs by the current flowing through the semiconductor, and supplies it to the control voltage amplifying unit 96. At the same time, the level of the control voltage Vs transmitted to the control voltage amplifier 96 is adjusted by changing the amount of current flowing through the semiconductor so that the voltage V _AB between the terminals A and B is constant.
The control voltage amplification unit 96 amplifies the control voltage Vs generated by the inter-terminal voltage monitoring unit 94 by a factor of g to generate a control voltage g × Vs and transmits the control voltage g × Vs to the power consumption unit 98.
The power consumption unit 98 causes the power semiconductor to consume power by flowing a required current Id to the power semiconductor in accordance with the control voltage g × Vs amplified by the control voltage amplification unit 96.

Thereby, in the pseudo load device 90 in which a plurality of pseudo load units 92 are connected in series, it is possible to consume surplus power that is no longer consumed in the observation device switched from the power supply state to the non-power supply state.
Further, the amount of current flowing through the semiconductor is adjusted so that the voltage V _AB applied between both terminals _AB is constant without depending on the current Id flowing through the power semiconductor provided in the power consuming unit 98. In the pseudo load device 90 in which a plurality of pseudo load units 92 are connected in series, it is possible to consume surplus power that is no longer consumed in the observation device that is switched from the power supply state to the non-power supply state.

<Starting of DC / DC Converter 72-1 for Output>
Next, an operation of starting only the output DC / DC converter 72-1 and supplying power only to the observation device 100-1 in the submarine device 20-1 will be described.
For example, as shown in Table 2, the control data D3 = 1, D4 = 0, D5 = 0, and D6 = 0 of the submarine device 20-1 may be changed.

First, at time t6 shown in FIG. 8 (d), the land control device 2 shown in FIG. 1 controls the device address (# 001) and control unique to the submarine device 20-1 in order to control the submarine device 20-1. Data is transmitted to the submarine device 20-1 via the submarine cable 16-1.
2 transmits the control data to the control unit 70 when the device address (# 001) of the received control data matches the device address (# 001) of the device. To do. 3 controls the output DC / DC converter 72-1 from the stopped state based on the control data D3 = 1, D4 = 0, D5 = 0, D6 = 0 input from the transmission unit 40. Switch to operating state.

Specifically, in FIG. 3, at time t6 to t7 shown in FIG. 8D, the output DC / DC converter 72-1 stops the converter based on the control data D3 = 1 input from the transmission unit 40. Switch from state to start state. As a result, the output DC / DC converter 72-1 is activated.
That is, in the output DC / DC converter 72-1, the switching element provided in the converter is ON / OFF controlled so that the magnetic energy generated in the primary winding induces a voltage in the secondary winding, A DC voltage is generated by a rectifying / smoothing circuit connected to the subsequent stage of the secondary winding.
The output DC / DC converter 72-1 is activated and a DC voltage is output from the output port P1 to the observation device 100-1, and the output voltage of the output port P1 gradually increases from 0V to 300V from time t6 to t7. At time t7, the current flowing through the pseudo load device 90 decreases to 3.4A to 2.55A.

That is, at time t7, the DC voltage output from the output DC / DC converter 72-1 to the observation apparatus 100-1 via the output port P1 reaches 300 V, and is consumed by the observation apparatus 100-1. Reaches the specified value, the voltage across the terminals I1 and I2 on the input side of the output DC / DC converter 72-1 (only a minute level) drops. In response to this, the current flowing through the pseudo load device 90 decreases from 3.4 A to 2.55 A.
At this time, DC power is supplied from the output DC / DC converter 72-1 to the output port P 1, and power is supplied from the output port P 1 to the observation device 100-1 disposed on the sea floor. Observation starts.

<Starting of DC / DC Converter 72-2 for Output>
Next, an operation of starting the output DC / DC converter 72-2 and supplying power to the observation device 100-2 in the submarine device 20-1 will be described.
For example, the control data for the submarine device 20-1 shown in Table 2 may be changed to D3 = 1, D4 = 1, D5 = 0, and D6 = 0.
1, the transmission unit 40 of the submarine device 20 shown in FIG. 2, the control unit 70 shown in FIG. 3, and the output DC / DC converter 72 at times t8 to t9 shown in FIG. The operation for -2 is substantially the same as the description for “starting the output DC / DC converter 72-1”, and the description thereof is omitted.
At time t9, the DC voltage output from the output DC / DC converter 72-2 to the observation apparatus 100-2 via the output port P2 reaches 300V, and the power consumed by the observation apparatus 100-2 is reduced. When the specified value is reached, the voltage (only a minute level) across the input terminals I1 and I2 of the output DC / DC converter 72-2 drops. In response to this, the current flowing through the pseudo load device 90 decreases from 2.55 A to 1.70 A.

<Starting of DC / DC Converter 72-3 for Output>
Next, the operation of starting the output DC / DC converter 72-3 and supplying power to the observation device 100-3 in the submarine device 20-1 will be described.
For example, the control data for the seabed device 20-1 shown in Table 2 may be changed to D3 = 1, D4 = 1, D5 = 1, and D6 = 0.
1, the transmission unit 40 of the seabed device 20 shown in FIG. 2, the control unit 70 shown in FIG. 3, and the output DC / DC converter 72 at times t <b> 10 to t <b> 11 shown in FIG. Since the operation for -3 is substantially the same as the description for “starting the output DC / DC converter 72-2”, the description thereof is omitted.
At time t11, the DC voltage output from the output DC / DC converter 72-3 to the observation device 100-3 via the output port P2 reaches 300 V, and the power consumed by the observation device 100-3 is reduced. When the specified value is reached, the voltage (only a minute level) across the input terminals I1 and I2 of the output DC / DC converter 72-3 drops. In response to this, the current flowing through the pseudo load device 90 decreases from 1.70 A to 0.85 A.

<Startup of DC / DC converter 72-4 for output>
Next, an operation of starting the output DC / DC converter 72-4 and supplying power to the observation device 100-3 in the submarine device 20-1 will be described.
For example, the control data for the submarine device 20-1 shown in Table 2 may be changed to D3 = 1, D4 = 1, D5 = 1, and D6 = 1.
1, the transmission unit 40 of the submarine device 20 shown in FIG. 2, the control unit 70 shown in FIG. 3, and the output DC / DC converter 72 at times t <b> 12 to t <b> 13 shown in FIG. Since the operation for -4 is substantially the same as the description for “starting the output DC / DC converter 72-2”, the description thereof is omitted.
At time t13, the DC voltage output from the output DC / DC converter 72-4 to the observation device 100-4 via the output port P4 reaches 300 V, and the power consumed by the observation device 100-4 is reduced. When the prescribed value is reached, the voltage (only a minute level) across the input terminals I1 and I2 of the output DC / DC converter 72-4 drops. In response to this, the current flowing through the pseudo load device 90 decreases from 0.85 A to 0.00 A.

As a result, surplus power that is no longer consumed in the observation device that has been switched from the power supply state to the non-power supply state can be consumed in the pseudo load device, and the surplus power that is no longer consumed with a simple configuration can be consumed. A supply system can be provided.
In addition, as the power consumed in the observation device switched from the non-power supply state to the power supply state, it can be applied from the power consumed in the pseudo load device, and the observation device and the pseudo load device with a simple configuration It is possible to provide an electric power supply system capable of easily giving and receiving surplus power to and from.

Second Embodiment
FIG. 9 is a block diagram showing a pseudo load unit which is one unit of the pseudo load device 90 used in the power supply system 1 according to the second embodiment of the present invention.
As shown in FIG. 9, the terminal A of the pseudo load unit 92-k is connected to the terminal B of the pseudo load unit 92- (k-1), and the terminal B of the pseudo load unit 92-k is connected to the pseudo load unit 92- ( k + 1) to terminal A.
As shown in FIG. 9, the pseudo load unit 92-k includes an inter-terminal voltage monitoring unit 104, a control voltage generation unit 106, and a power consumption unit 108, and each unit is connected in parallel between terminals A and B. .
The inter-terminal voltage monitoring unit 104 includes a semiconductor used for monitoring the voltage V _AB applied between the terminals A and B, a voltage control semiconductor used for voltage control, and a passive component associated with the voltage control semiconductor. The voltage V _AB between the terminals A and B is monitored, and the monitoring voltage Vw is generated to make the voltage V _AB between the terminals A and B constant without depending on the current Id flowing through the power consumption unit 108. And transmitted to the control voltage generator 106.
The control voltage generation unit 106 includes a signal amplification semiconductor used for signal amplification and a passive component associated with the signal amplification semiconductor, and amplifies the monitoring voltage Vw generated by the inter-terminal voltage monitoring unit 104 by g times. Thus, a required control voltage g × Vw is generated and supplied to the power consumption unit 108.
The power consuming unit 108 is composed of a power semiconductor, and a required current is supplied to the power semiconductor in accordance with the control voltage g × Vw generated by the control voltage generating unit 106, so that the power in the power semiconductor To consume. Note that the power semiconductor provided in the power consumption unit 108 may be any one of a power transistor, a field effect transistor, and an IGBT.

Next, the operation of the pseudo load unit 92-k shown in FIG. 9 will be described.
The inter-terminal voltage monitoring unit 104 monitors the voltage V _AB between the terminals A and B, and makes the voltage V _AB between the terminals A and B constant without depending on the current Id flowing through the power consumption unit 108. A monitoring voltage Vw is generated and transmitted to the control voltage generator 106.
The control voltage generation unit 106 amplifies the monitoring voltage Vw received from the inter-terminal voltage monitoring unit 104 by a factor of g to generate a required control voltage g × Vw and supplies it to the power consumption unit 108.
The power consuming unit 108 is composed of a power semiconductor, and a required current is supplied to the power semiconductor in accordance with the control voltage g × Vw generated by the control voltage generating unit 106, so that the power in the power semiconductor To consume.
In this way, the pseudo load device 90 is configured such that, for example, only 50 pseudo load units having a voltage V _AB applied between both terminals A and B of 8V are connected in series.

Thereby, in the pseudo load device 90 in which a plurality of pseudo load units 92 are connected in series, it is possible to consume surplus power that is no longer consumed in the observation device switched from the power supply state to the non-power supply state.
Further, the amount of current flowing through the semiconductor is adjusted so that the voltage V _AB applied between both terminals _AB is constant without depending on the current Id flowing through the power semiconductor provided in the power consuming unit 108. In the pseudo load device 90 in which a plurality of pseudo load units 92 are connected in series, it is possible to consume surplus power that is no longer consumed in the observation device that is switched from the power supply state to the non-power supply state.

<Third Embodiment>
FIG. 10 is a block diagram showing a pseudo load unit which is one unit of the pseudo load device 90 used in the power supply system 1 according to the third embodiment of the present invention.
As shown in FIG. 10, the terminal A of the pseudo load unit 92-k is connected to the terminal B of the pseudo load unit 92- (k-1), and the terminal B of the pseudo load unit 92-k is connected to the pseudo load unit 92- ( k + 1) to terminal A.
The pseudo load unit 92-k includes a control unit 114, an amplification unit 116, and a power consumption unit 118, and each unit is connected in parallel between the terminals A and B.
The control unit 114 is configured by a voltage control semiconductor used for voltage control and passive components associated therewith, and monitors the voltage V _AB applied between the terminals A and B and depends on the current flowing through the power consumption unit 118. Instead, the control voltage Vs is generated and transmitted to the amplifier 116 so that the voltage V _AB between the terminals A and B becomes constant.
The amplifying unit 116 includes a signal amplifying semiconductor used for signal amplification and a passive component associated with the signal amplification. The amplifying unit 116 amplifies the control voltage generated by the control unit 114 g times to obtain the control voltage g × Vs. It is generated and transmitted to the power consumption unit 118.
The power consuming unit 118 is configured by a power semiconductor, and causes the power semiconductor to consume power by causing a current to flow through the power semiconductor in accordance with the control voltage g × Vs generated by the amplifying unit 116. The power semiconductor provided in the power consumption unit 98 may be any one of a power transistor, a field effect transistor, and an IGBT.

Next, the operation of the pseudo load unit 92-k shown in FIG. 10 will be described.
The control unit 114 monitors the voltage V _AB applied between the terminals A and B, and controls the voltage V _AB between the terminals A and B to be constant without depending on the current flowing through the power consumption unit 118. The voltage Vs is transmitted to the amplifying unit 116.
The amplifying unit 116 amplifies the control voltage received from the control unit 114 by a factor of g and transmits the control voltage g × Vs to the power consuming unit 118.
The power consumption unit 118 causes power to be consumed in the power semiconductor by causing a current to flow through the power semiconductor in accordance with the control voltage g × Vs received from the amplification unit 116.
In this way, the pseudo load device 90 is configured such that, for example, only 50 pseudo load units having a voltage V _AB applied between both terminals A and B of 8V are connected in series.

Thereby, in the pseudo load device 90 in which a plurality of pseudo load units 92 are connected in series, it is possible to consume surplus power that is no longer consumed in the observation device switched from the power supply state to the non-power supply state.
Further, the amount of current flowing through the semiconductor is adjusted so that the voltage V _AB applied between both terminals _AB is constant without depending on the current Id flowing through the power semiconductor provided in the power consuming unit 118. In the pseudo load device 90 in which a plurality of pseudo load units 92 are connected in series, it is possible to consume surplus power that is no longer consumed in the observation device that is switched from the power supply state to the non-power supply state.

<Fourth embodiment>
FIG. 11 is a block diagram for explaining a configuration of the submarine device 20 provided in the power supply system 1 according to the fourth embodiment of the present invention. In addition, since the code | symbol shown in FIG. 11 and the same code | symbol shown in FIG. 2 are the same structures, the description is abbreviate | omitted.
The submarine device 20 according to the fourth embodiment is different from the first embodiment in which the pseudo load device 90 is connected to the control unit 70 in that the pseudo load device 90 is connected to the power receiving unit 60.
Specifically, the pseudo load device 90 is connected to both contact points of the power supply path path relay 62 via output ports Pr1 and Pr2.

FIG. 12 shows a combination of the main DC / DC converters 64 and 66 and the output DC / DC converters 72-1 to 72-4 shown in FIG. 11 used in the power supply system 1 according to the fourth embodiment of the present invention. It is a block diagram for demonstrating a detailed connection relationship.
Specifically, the pseudo load device 90 is connected to the power supply paths 32 b and 32 d and is connected to the primary side of the main DC / DC converters 64 and 66, and supplies power according to control by the land control device 4. When the contact of the road path relay 62, the switch SW65, and / or the contact of the switch SW67 is switched from the closed state to the open state, the observation devices 100-1 to 100-100 that can be connected to the ports P1 to P4 of the output unit 80 The surplus power that could not be consumed in -4 can be consumed by the pseudo load device 90.

As a result, surplus power that is no longer consumed in the observation device that has been switched from the power supply state to the non-power supply state can be consumed in the pseudo load device, and the surplus power that is no longer consumed with a simple configuration can be consumed. A supply system can be provided.
In addition, as the power consumed in the observation device switched from the non-power supply state to the power supply state, it can be applied from the power consumed in the pseudo load device, and the observation device and the pseudo load device with a simple configuration It is possible to provide an electric power supply system capable of easily giving and receiving surplus power to and from.

<Effect of the invention>
The pseudo load unit of the present invention includes a terminal voltage monitoring unit, a control voltage amplifying unit, and a power consuming unit composed of a semiconductor element and a passive element associated therewith. Each block is designed and manufactured with high accuracy. (Adjustment) is possible.
Therefore, since a pseudo load unit with little characteristic variation can be realized at a relatively low cost, the expected characteristics can be obtained even when connecting in multiple stages. In this respect, there is an advantage in characteristics over the configuration in which Zener diodes used in the prior art are connected in multiple stages.
Moreover, since the pseudo load unit of the present invention is configured by the terminal voltage monitoring unit, the control voltage amplifying unit, and the power consuming unit, than the configuration of simply consuming excess power in the Zener diode as in the prior art, There is an advantage that voltage stability is remarkably excellent.

<Configuration, operation and effect of exemplary embodiment of the present invention>
<First aspect>
The power supply system 1 of this aspect includes a parent device having a land power supply device 10 (power supply means) and a land control device 2 (control means), and a submarine device 20 (child device) connected from the parent device via a submarine cable 16. The submarine device 20 (child device) converts the first DC power supplied to the primary side to the second DC power and outputs the second DC power to the secondary side. Main DC / DC converters 64, 66 (DC power conversion unit), control unit 70 (power distribution unit) and output unit for distributing second DC power to pseudo load device 90 and at least one observation device 100 (device) The pseudo load device 90 is connected to the primary side or the secondary side of the main DC / DC converters 64 and 66, and the number of observation devices 100 connected to the control unit 70 and the output unit 80 is increased or decreased. Depending on the first straight Characterized in that it consume the excess power of the power or the second DC power.
According to this aspect, the submarine device 20 (child device) converts the first DC power supplied to the primary side by the main DC / DC converters 64 and 66 into the second DC power and outputs the second DC power to the secondary side. The control unit 70 and the output unit 80 distribute the second DC power to the pseudo load device 90 and at least one observation device 100 (device), and the pseudo load device 90 is the primary side of the main DC / DC converters 64 and 66. Alternatively, surplus power of the first DC power or the second DC power is consumed according to the increase or decrease of the number of observation devices 100 connected to the secondary side and connected to the control unit 70 and the output unit 80.
As a result, surplus power that is no longer consumed in the observation device that has been switched from the power supply state to the non-power supply state can be consumed in the pseudo load device, and the surplus power that is no longer consumed with a simple configuration can be consumed. A supply system can be provided.
In addition, as the power consumed in the observation device switched from the non-power supply state to the power supply state, it can be applied from the power consumed in the pseudo load device, and the observation device and the pseudo load device with a simple configuration It is possible to provide an electric power supply system capable of easily giving and receiving surplus power to and from.

<Second aspect>
The pseudo load device 90 of this aspect includes a plurality of pseudo load units 92 connected in series, and each pseudo load unit 92 receives a voltage V _AB applied between both terminals A and B of the pseudo load unit 92. An inter-terminal voltage monitoring unit 94 that generates a control voltage Vs by monitoring and adjusts the level of the control voltage Vs so that the voltage V _AB applied between the terminals A and B is constant, and a terminal The control voltage amplifying unit 96 that amplifies the control voltage Vs generated by the inter-voltage monitoring unit 94 by a factor of g to generate the control voltage g × Vs, and the control voltage generated by the control voltage amplifying unit 96 and a power consumption unit 98 for consuming power in the power semiconductor by flowing a required current Id to the power semiconductor in accordance with g × Vs.
According to this aspect, each pseudo load unit 92 generates a control voltage Vs by monitoring the voltage V _AB applied between the terminals A and B of the pseudo load unit 92 by the inter-terminal voltage monitoring unit 94. In addition, the level of the control voltage Vs is adjusted so that the voltage V _AB applied between the terminals A and B is constant, and the control voltage amplifying unit 96 is generated by the inter-terminal voltage monitoring unit 94. The control voltage Vs is amplified by a factor of g to generate a control voltage g × Vs, and the power consumption unit 98 requires a power semiconductor according to the control voltage g × Vs generated by the control voltage amplifier 96. The power semiconductor is made to consume power by flowing the current Id.
Thereby, in the pseudo load device 90 in which a plurality of pseudo load units 92 are connected in series, it is possible to consume surplus power that is no longer consumed in the observation device switched from the power supply state to the non-power supply state.
In addition, as the power consumed in the observation device switched from the non-power supply state to the power supply state, it can be applied from the power consumed in the pseudo load device, and the observation device and the pseudo load device with a simple configuration And exchange of surplus power with can be easily performed.

<Third aspect>
The inter-terminal voltage monitoring unit 94 of this aspect includes a semiconductor for monitoring the voltage V _AB applied between both terminals A and B, and the current Id flowing in the power semiconductor provided in the power consuming unit 98. The control voltage Vs is generated by adjusting the amount of current flowing through the semiconductor so that the voltage V _AB applied between the terminals A and B is constant without depending on the above.
According to this aspect, the inter-terminal voltage monitoring unit 94 includes a semiconductor for monitoring the voltage V _AB applied between both terminals A and B, and the power semiconductor provided in the power consuming unit 98 is used. Regardless of the flowing current Id, the control voltage Vs is generated by adjusting the amount of current flowing through the semiconductor so that the voltage V _AB applied between the terminals _AB is constant.
Thus, the amount of current flowing through the semiconductor is adjusted so that the voltage V _AB applied between both terminals A and B is constant without depending on the current Id flowing through the power semiconductor provided in the power consuming unit 98. In the pseudo load device 90 in which a plurality of pseudo load units 92 are connected in series, it is possible to consume surplus power that is no longer consumed in the observation device switched from the power supply state to the non-power supply state.

<4th aspect>
The power semiconductor according to this aspect is any one of a transistor, a field effect transistor, and an IGBT.
According to this aspect, since the power semiconductor is any one of a transistor, a field effect transistor, and an IGBT, the power applied between both terminals can be consumed in the power semiconductor.
As a result, surplus power that is no longer consumed in the observation device that is switched from the power supply state to the non-power supply state can be consumed in the pseudo load device.

<5th aspect>
When the number of observation devices 100 (equipment) connected to the control unit 70 (power distribution unit) increases, the pseudo load device 90 according to this aspect reduces the current flowing through the pseudo load device 90 and causes the control unit 70 to When the number of connected observation devices 100 (devices) decreases, the current flowing through the pseudo load device 90 increases.
According to this aspect, when the number of observation devices 100 connected to the control unit 70 increases, the pseudo load device 90 reduces the current flowing through the pseudo load device 90 and the observation device connected to the control unit 70. When the number of 100 drops, the current flowing through the pseudo load device 90 increases.
As a result, the pseudo load device 90 can consume surplus power according to an increase or decrease in the number of observation devices 100.
Thereby, when the number of observation devices 100 connected to the control unit 70 decreases, surplus power that is no longer consumed in the observation device 100 switched from the power supply state to the non-power supply state can be consumed in the pseudo load device. It is possible to provide a power supply system capable of consuming surplus power that is no longer consumed with a simple configuration.
In addition, when the number of observation devices 100 connected to the control unit 70 increases, power consumed in the observation device 100 that has been switched from the non-power supply state to the power supply state is consumed in the pseudo load device. Therefore, it is possible to provide a power supply system that can be allocated from the generated power and that can easily exchange surplus power between the observation device and the pseudo load device with a simple configuration.

<Sixth aspect>
The pseudo load device 90 according to this aspect is a pseudo load device including a plurality of pseudo load units 92 connected in series, and each pseudo load unit 92 is applied between both terminals A and B of the pseudo load unit 92. Between the terminals that monitor the voltage V _AB being generated to generate the control voltage Vs and adjust the level of the control voltage Vs so that the voltage V _AB applied between both terminals _AB is constant A voltage monitoring unit 94; a control voltage amplifying unit 96 that amplifies the control voltage Vs generated by the inter-terminal voltage monitoring unit 94 g times to generate a control voltage g × Vs; and a control voltage amplifying unit 96 And a power consuming unit 98 that consumes power in the power semiconductor by causing a required current Id to flow in the power semiconductor in accordance with the control voltage g × Vs generated by the above.
According to this aspect, each pseudo load unit 92 generates a control voltage Vs by monitoring the voltage V _AB applied between the terminals A and B of the pseudo load unit 92 by the inter-terminal voltage monitoring unit 94. In addition, the level of the control voltage Vs is adjusted so that the voltage V _AB applied between the terminals A and B is constant, and the control voltage amplifying unit 96 is generated by the inter-terminal voltage monitoring unit 94. The control voltage Vs is amplified by a factor of g to generate a control voltage g × Vs, and the power consumption unit 98 requires a power semiconductor according to the control voltage g × Vs generated by the control voltage amplifier 96. The power semiconductor is made to consume power by flowing the current Id.
Thereby, in the pseudo load device 90 in which a plurality of pseudo load units 92 are connected in series, it is possible to consume surplus power that is no longer consumed in the observation device switched from the power supply state to the non-power supply state.
In addition, as the power consumed in the observation device switched from the non-power supply state to the power supply state, it can be applied from the power consumed in the pseudo load device, and the observation device and the pseudo load device with a simple configuration And exchange of surplus power with can be easily performed.

As mentioned above, although this invention was demonstrated to the example which connected the main | ground parent | device and the submarine child device via the submarine cable, this invention is not limited to this, For example, near the crater of a volcano The present invention can be applied to any scene where power is supplied to a child device installed in a remote place, such as when power is supplied to an installed eruption monitoring device or when a water level monitoring device of a dam is supplied.
Further, regarding power supply on land, the present invention can also be applied to a system that supplies power to each home or a room of each home by a direct current method (DC).

DESCRIPTION OF SYMBOLS 1 ... Electric power supply system, 2 ... Land control device (control means), 4 ... Control cable, 10 ... Land power supply device (power supply means), 11 ... Ground, 12 ... Power line, 16 ... Submarine cable, 20 ... Submarine device (child) Device), 22 ... functional sea earth, 40 ... transmission unit, 42 ... cable, 62 ... feeding path path relay, 64, 66 ... main DC / DC converter, 65, 67 ... switch SW, 50 ... drive power supply unit, 60 ... power receiving unit , 70 ... control unit, 72 ... DC / DC converter for output, 80 ... output unit, 90 ... pseudo load device, 92 ... pseudo load unit, 94, 104 ... terminal voltage monitoring unit, 96 ... control voltage amplification unit, 98, 108, 118 ... power consumption unit, 100 ... observation device, 106 ... control voltage generation unit, 114 ... control unit, 116 ... amplification unit

Claims (2)

A parent device having power supply means and control means;
A child device connected via a cable from the parent device;
A pseudo load device connected to the slave device, and a power supply system comprising:
The child device is
A DC power converter that converts the first DC power supplied to the primary side into second DC power and outputs the second DC power to the secondary side;
A power distribution unit that distributes to at least one device,
The pseudo load device is:
It has a pseudo load unit of n stages (n is a natural number of 2 or more ),
Each stage of the pseudo load unit is
A terminal voltage monitoring unit, a control voltage amplification unit, and a power consumption unit;
The terminal voltage monitoring unit, the control voltage amplification unit, and the power consumption unit are connected in parallel between both terminals of the pseudo load unit,
The inter-terminal voltage monitoring unit is configured by a semiconductor used for monitoring a voltage applied between both terminals of the pseudo load unit, and a passive component associated with the semiconductor, and the voltage between the terminals is constant. Generating a control voltage to transmit to the control voltage amplifier,
The control voltage amplifying unit amplifies the control voltage and transmits it to the power consuming unit,
The power consuming unit is composed of a power semiconductor, and a voltage between the terminals is constant by flowing a required current through the power semiconductor in accordance with the control voltage amplified by the control voltage amplifier. It consumes power so that
The dummy load device, the power supply system, characterized in Tei Rukoto connected to the primary or secondary side of the DC power conversion unit. The power supply system according to claim 1, wherein the power semiconductor constituting the power consumption unit is one of a transistor, a field effect transistor, and an IGBT .

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