JP2014003729A - Dc distribution board system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a construction cost of a DC distribution board system composed of a plurality of DC distribution boards by downsizing the DC distribution boards by dispensing with installation of a voltage sensor in a DC distribution board for each branch feeder.SOLUTION: One of a plurality of DC distribution boards 10a, 10b, ... 10z comprises a DC voltage sensor 6 for detecting voltage of a branch feeder corresponding to the DC distribution board. All of the plurality of DC distribution boards comprise DC current sensors 7a, 7b, ... 7z for detecting current of branch feeders 3a, 3b, ... 3z corresponding to the DC distribution boards. Data on power and power amounts calculated by all of protection measurement devices 8a, 8b, ... 8z in the plurality of DC distribution boards are transmitted from the protection measurement devices to a monitoring control device 9 so that power and power amounts used by a plurality of DC loads of the branch feeders are monitored by the monitoring control device in a lump.

Description

  The present invention relates to a DC switchboard system that is used to monitor the power used by DC loads of a plurality of feeders branched from a DC bus.

In conventional DC switchboard systems that collectively monitor power and electric energy, the system configuration is often the same as the system configuration considering the phase synchronization between the voltage signal and current signal of the AC switchboard system. In order to measure the DC voltage for each branch feeder, it was necessary to provide a DC voltage sensor for each branch feeder and measure the power and the amount of power based on the voltage signal and the current data for each branch feeder. .
That is, as shown in FIG. 5, DC voltage sensors 6a, 6b,... 6z and DC current sensors 7a, 7b,... 7z are provided for each branch feeder 3a, 3b,. The sensor signals are subjected to signal processing by the voltage signal conversion means 81 and the current signal conversion means 82 in the protective measuring devices 8a, 8b,... 8z provided for each branch feeder 3a, 3b,. The converted signal is converted into a digital signal by an A / D (analog-digital) conversion means. Each signal is sampled at regular intervals for each of the protective measuring devices 8a, 8b,... 8z, and a certain number of sampling data is added by the calculation means 84 for each protective measuring device 8a, 8b,. Divide by number and average data. In order to perform power measurement, power data is obtained by integrating the averaged voltage and current data. In order to calculate the electric energy, the electric energy is calculated by calculating the electric energy by integrating the electric power data in a certain time.
The power and power amount values calculated by the calculation means 84 for each of the protective measuring devices 8a, 8b,... 8z are transmitted to the monitoring control device 9 via the transmission means 10 and Monitor the values collectively.

  In addition, there exists the following patent document 1 as a prior art document of the electrical measurement apparatus of the switchboard in an alternating current system.

JP 2002-112411 A

In the DC switchboard system shown in FIG. 5, DC voltage sensors 6a, 6b,... 6z and DC current sensors 7a, 7b,... 7z are provided for each branch feeder 3a, 3b,. Each sensor signal is signaled by a voltage signal conversion means 81 and a current signal conversion means 82 in the protective measuring devices 8a, 8b,... 8z provided for each branch feeder 3a, 3b,. Converted into a voltage level that can be processed, and the converted signal is converted into a digital signal by an A / D (analog-to-digital) conversion means, and each signal is for each protection measuring device 8a, 8b,. Are sampled at regular intervals, and for each of the protective measuring devices 8a, 8b,... 8z, a certain number of sampling data is added by the respective calculation means 84 of the protective measuring devices 8a, 8b,. The calculation means 84 divides the data by the number of samplings and averages the data. The voltage and current data averaged by the calculation means 84 are integrated to obtain power data, and the power data is integrated for a certain period of time. The power and the electric energy value calculated and calculated by the calculating means 84 for each of the protective measuring devices 8a, 8b,... 8z are transmitted to the monitoring control device 9 via the transmission means 11, and the monitoring control device 9 Since it is a system that collectively monitors the electric energy value, a voltage sensor and a current sensor are required for each branch feeder 3a, 3b,... 3z, and a voltage signal conversion means, power (W ) And electric energy (WH) are required, and the system construction cost is expensive.

The present invention has been made in view of the above-described circumstances, and it is possible to reduce the size of a DC distribution board by eliminating the need to provide a voltage sensor for each branch feeder in the DC distribution board. The purpose is to reduce the construction cost of a DC switchboard system comprising:
In addition, it is possible to reduce the size of the DC switchboard by eliminating the need to calculate the power and the amount of power with the calculation device in the DC switchboard for each branch feeder, thereby reducing the construction cost of a DC switchboard system consisting of multiple DC switchboards. The purpose is to reduce the cost.

The DC switchboard system according to the present invention is
In a DC switchboard system comprising a plurality of DC switchboards installed corresponding to each of a plurality of branch feeders branched from a DC bus and connected to a DC load via a circuit breaker, respectively.
One of the plurality of DC distribution boards has a DC voltage sensor for detecting the voltage of the corresponding branch feeder,
All of the plurality of DC distribution boards have a DC current sensor that detects the current of the corresponding branch feeder,
All of the plurality of DC distribution boards have a protective measuring device having a protection function of detecting an abnormality in current and voltage of the corresponding branch feeder and tripping the circuit breaker of the corresponding branch feeder,
Data of the voltage detected by the DC voltage sensor is transmitted to the protective measuring device of the DC switchboard without the DC voltage sensor,
Power used by the DC load of the corresponding branch feeder from the current data and the voltage data detected by the corresponding DC current sensor in all of the protective measuring devices of the plurality of DC distribution boards. And calculate the amount of power,
The data of the electric power and the electric energy calculated by all the protection measurement devices of the plurality of DC distribution boards are transmitted from the protection measurement device to the monitoring control device and used by the DC loads of the plurality of branch feeders. Electric power and electric energy are collectively monitored by the monitoring control device.

The present invention provides a DC switchboard system comprising a plurality of DC switchboards installed corresponding to each of a plurality of branch feeders branched from a DC bus and connected to a DC load via a circuit breaker, respectively, and incorporating the corresponding circuit breakers. And a DC current sensor in which one of the plurality of DC switchboards detects a voltage of the corresponding branch feeder, and all of the plurality of DC switchboards detect a current of the corresponding branch feeder. A protective measuring device having a protective function for detecting an abnormality in the current and voltage of the corresponding branch feeders and tripping the circuit breaker of the corresponding branch feeders. The voltage data detected by the DC voltage sensor is transmitted to the protective measuring device of the DC switchboard without the DC voltage sensor. All of the protective measuring devices of the plurality of DC distribution boards use the DC load of the corresponding branch feeder from the current data and the voltage data detected by the corresponding DC current sensor. Power and power amount are calculated, and the power and power amount data calculated by all the protection measurement devices of the plurality of DC distribution boards are transmitted from the protection measurement device to the monitoring control device, and the plurality of branch feeders Since the power and amount of power used by the DC load are collectively monitored by the monitoring and control device, it is not necessary to incorporate a voltage sensor in each DC distribution board for each branch feeder, and a plurality of branches Among DC switchboards for each feeder, other than DC switchboards with built-in voltage sensors, multiple DC switchboards without built-in voltage sensors have the same configuration. It can be an effect of capable of cost reduction of the construction cost of the DC distribution panel system comprising a plurality of DC distribution panel.

It is a connection diagram which shows an example of the system configuration | structure of the DC switchboard system applied to Embodiment 1 and Embodiment 2 of this invention. It is a figure which shows Embodiment 1 of this invention, and is a figure which illustrates the relationship of the voltage in FIG. 1, an electric current, a data average period, and a polling period. It is a figure which shows Embodiment 3 of this invention, and is a connection diagram which shows the other example of the system configuration | structure of a DC switchboard system. It is a figure which shows Embodiment 4 of this invention, and is a connection diagram which shows the further another example of the system configuration | structure of a DC switchboard system. It is a figure which shows the example of the system configuration | structure of the conventional DC switchboard system.

Embodiment 1 FIG.
A first embodiment of the present invention will be described below with reference to FIGS. FIG. 1 is a connection diagram illustrating an example of a system configuration of a DC switchboard system, and FIG. 2 is a diagram illustrating the relationship among voltage, current, data average period, and polling period in FIG.

  In FIG. 1, AC power of an AC power system (not shown) is converted into DC power by an AC / DC converter 1, and the DC power is supplied to a DC bus 2. As shown in the figure, a plurality of branch feeders 3a, 3b,... 3z are connected to the DC bus 2, and circuit breakers 4a, 4b,. DC loads 5a, 5b,... 5z, such as a data center (storage center for various electronic data), are connected.

  Each of the plurality of branch feeders 3a, 3b, ... 3z is provided with DC distribution boards 10a, 10b, ... 10z including the circuit breakers 4a, 4b, ... 4z. Of the switchboards 10a, 10b,... 10z, only the DC switchboard 10a corresponding to one branch feeder 3a has a built-in DC voltage sensor 6 for detecting the voltage of the branch feeder 3a, and the other branch feeders 3b,. .. DC power distribution sensors 10b,... 10z corresponding to 3z are not provided with DC voltage sensors for detecting the voltages of the corresponding branch feeders 3b,.

DC current sensors 7a, 7b,... 7z for detecting DC current are installed in each of a plurality of branch feeders 3a, 3b,... 3z as shown, and corresponding DC distribution boards 10a, 10b,. -Built in 10z.
In addition, each of the DC switchboards 10a, 10b,... 10z has a protection function that trips the corresponding circuit breakers 4a, 4b,... 4z when the corresponding branch feeders 3a, 3b,. And protective measuring devices 8a, 8b,...
Here, the protective measuring device 8a built in the DC switchboard 10a measures the voltage and current of the corresponding branch feeder 3a via the DC voltage sensor 6 and the DC current sensor 7a, and the other DC switchboards 10b,. · The protective measuring device 8b built in 10z, ... 8z measures only the current of the corresponding branch feeder 3b, ... 3z without measuring the voltage via the corresponding DC current sensor 7b, ... 7z. To do.

The protective measuring device 8a built in the DC switchboard 10a converts the voltage signal conversion means 81 for converting the output of the DC voltage sensor 6 into a voltage that can be measured and the voltage of the DC current sensor 7a into a voltage that can be measured. Current signal conversion means 82, A / D conversion means 83 for converting the analog signal output from voltage signal conversion means 81 and the analog signal output from current signal conversion means 82 into a digital signal, and digital sampling of the sampled voltage A calculation means 84 for calculating the averaging process of each of the digital sampling values of the value and the sampled current, and a transmission means 85 for transmitting the average data of the voltage and current as the calculation result of the calculation means 84 to the outside have. In addition, illustration is abbreviate | omitted about the protection function part which manages the protection function which carries out trip interruption | blocking of the circuit breaker 4a corresponding to the time of abnormality of the branch feeder 3a.
As a specific method of the averaging process, the voltage signal and the current signal are sampled at regular intervals, respectively, a fixed number of sampling data is added, and the data is averaged by dividing by each sampling number.

The DC distribution boards 10b,... 10z corresponding to the other branch feeders 3b,... 3z have voltage signal conversion means for converting the output of the DC voltage sensor 6 and the DC voltage sensor into a voltage that can be measured. None of the protective measuring devices 8b,... 8z are provided with a current signal converting means 82 for converting the output of the DC current sensors 7b,. An A / D conversion unit 83 that converts an analog signal output from the conversion unit 82 into a digital signal, a calculation unit 84 that performs an averaging process for each of the digital sampling values of the sampled current, The transmission means 85 for transmitting each averaged data of the current as the calculation result to the outside, and the internal configuration and the function are all the same. Note that for any of the protective measuring devices 8b,... 8z, a protection function unit that manages a protection function that trips and shuts off the corresponding circuit breakers 4b,... 4z when the corresponding branch feeders 3b,. The illustration is omitted for.
As a specific method of the averaging process, the current signal is sampled at a constant interval, a fixed number of sampling data is added, and the data is averaged by dividing by the sampling number.

In order to perform power measurement, power data is obtained by performing an operation of integrating the averaged voltage data and the averaged current data.
In order to calculate the electric energy, the electric energy data is obtained by performing an operation of integrating the electric power data in a certain time.

In the first embodiment, the voltage data averaged by the calculation means 84 of the protection measuring device 8a in the DC switchboard 10a of the branch feeder 3a is transmitted by the transmission master station 91 of the monitoring control device 9 by the polling transmission method. Collected regularly via
The transmission master station 91 periodically transmits the collected averaged DC bus voltage data to the protection measuring devices 8b,... 8z via the transmission line 11 by the polling transmission method.
In the protective measuring devices 8b,... 8z, the averaged DC bus voltage data and the averaged current data are obtained from the averaged DC bus voltage transmitted and the current data previously averaged. Is generated, and power data is generated by adding the generated power data over a certain period of time.
The power data and power amount data generated by the protective measuring devices 8a, 8b,... 8z for each branch feeder 3a, 3b,... 3z are transmitted to the monitoring control device 9 via the transmission line 11. The monitoring control device 9 performs collective monitoring of the power consumption and the power consumption of the DC loads 5a, 5b,... 5z of the branch feeders 3a, 3b,.

  The relationship between the DC voltage, the DC current, the data average period, and the transmission polling period is, for example, as illustrated in FIG.

  That is, the average voltage data timing of the protective measuring device 8a is calculated by executing the above-described average processing on the voltage data in the protective measuring device 8a at the timings Va1, Va2,... Van, Van + 1. Has been.

The voltage data average period a1, a2, a3 is the voltage data average timing immediately before the voltage data acquisition timing Pa1, Pa2, Pa3, Pa4, Pa5.For example, at the voltage data acquisition timing Pa2, the voltage data average of the protective measuring device The voltage data obtained by averaging the voltage data in the period from Va2 to Va4 is used as the average voltage data, and is transmitted to the transmission master station at voltage data acquisition timing Pa2 via transmission.

The voltage data average timing t1 is about 16 to 100 ms since the time difference variation of the voltage data average periods a1, a2, and a3 becomes smaller as the interval is shorter.
For example, if the interval of the voltage data average timing t1 is lengthened, the voltage data average timing can be generated twice or three times during the polling period t2. In this case, the variation of the voltage data average timing generates an error of about 33%, which is 2/3 at the maximum. On the other hand, if the interval of the voltage data average timing t1 is shortened, the voltage data average timing is, for example, 9 It can be generated 10 times or 10 times. In this case, the variation in the voltage data average timing is 9/10 at maximum, resulting in an error of about 10%, and the error is reduced.

  In the transmission master station, it is necessary to transmit the acquired voltage data from each protection measurement device 8b to the protection measurement device 8z.For example, from the transmission master station at the timing of the voltage data slave station transmission timing Pb1, Pb2, A transmission assignment command is transmitted via transmission to each of the protective measuring devices 8a to 8z.

The transmission master station commands voltage data transmission to the protection measuring device 8a, and the required time until the protection measuring device 8a transmits is tda. The required time varies depending on the protection measuring device.
The required time similar to the required time tda of the protective measuring device 8a is generated for the number of protective measuring devices 8a, 8b,... 8z (tda, tdb,... Tdz), and this total time (tda + tdb + ... + tdz ) Is the polling cycle t2, the polling cycle t2 can be shortened by shortening the required time. The shorter the polling period t2, the shorter the transmission delay of the voltage data and the better the power measurement accuracy. However, if it is extremely short, the transmission path becomes congested and the traffic becomes high, causing transmission abnormalities. .

The voltage data transmitted from the transmission master station to the protection measurement device 8b is used as voltage data in the protection measurement device 8b.
In the protective measuring device 8b, the current is calculated at the timings of Ab1, Ab2,... Abn, Abn + 1 in the figure, and the current measurement value is calculated.

t3 is a calculation period of current measurement.
Based on these current measurement values and voltage data, electric power and electric energy calculation are performed.
The electric power and electric energy data are transmitted from the protection measuring device 8b to the parent station when the parent station requests the electric power and electric energy measurement values.

  According to the first embodiment, it is not necessary to incorporate a voltage sensor in each of the DC switchboards 10a, 10b,... 10z for each branch feeder 3a, 3b,. , 3b,..., 10z, a plurality of DC switchboards 10b,... 10z that do not incorporate voltage sensors other than DC switchboard 10a that incorporates voltage sensor 6 are DC distribution boards 10a, 10b,. Any of them can have the same configuration and the same function, and the construction cost of a DC switchboard system composed of a plurality of DC switchboards can be reduced.

Embodiment 2. FIG.
The second embodiment is different from the first embodiment in FIG. 1 in that each protection measuring device 8a in each DC distribution board 10a, 10b,... 10z of each branch feeder 3a, 3b,. , 8b,... 8z, without calculating the power and the amount of power, each protective measuring device 8a, 8b,. The averaged current data is transmitted to the transmission master station 91 of the monitoring control device 9, and the averaged current data transmitted from the protection measuring device 8a and the protection measuring devices 8a, 8b,. From the averaged current data, the CPU 92 of the supervisory controller 9 calculates the power consumption and power consumption of the DC loads 5a, 5b,... 5z of the branch feeders 3a, 3b,. Branch feeder 3a, 3b, ... Use power data and use power amount data for each z are generated, and the DC load 5a, 5b,... 5z of each branch feeder 3a, 3b,. Collective monitoring of power consumption and power consumption is performed.

  According to the second embodiment, the DC distribution board can be reduced in size by not having to calculate the electric power and the electric energy by the calculation device in the DC distribution board for each branch feeder, and is composed of a plurality of DC distribution boards. The construction cost of the DC switchboard system can be reduced.

Embodiment 3 FIG.
As illustrated in FIG. 3, the third embodiment is different from FIG. 1 in that the DC voltage sensor 6 is not provided in the DC switchboard 10a but is connected to the DC bus 2 to connect the DC switchboards 10a, 10b,. The voltage output is transmitted from the transmission unit 12 having the same functions as the voltage signal conversion unit 81 and the A / D conversion unit 83 in FIG. 1 to the transmission master station 91 of the monitoring control device 9. It is what you do.
The generation of power data and power amount data may be the same as the generation in any of the DC switchboard systems of the first and second embodiments described above.

  According to the third embodiment, it is not necessary to incorporate a voltage sensor in each of the DC switchboards 10a, 10b,... 10z for each branch feeder 3a, 3b,. , 3b,... 3z, all of the plurality of DC distribution boards 10a, 10b,... 10z having no built-in voltage sensor have the same configuration and the same function. In addition, the construction cost of a DC switchboard system composed of a plurality of DC switchboards can be reduced.

Embodiment 4 FIG.
As illustrated in FIG. 4, the fourth embodiment is an example in which the master station device 91 in FIG. 3 is not provided in the monitoring control device 9 unlike FIG. 3, and the DC voltage sensor 6 is installed in the DC switchboard 10 a. Without being provided, it is connected to the DC bus 2 and installed independently of the DC switchboards 10a, 10b,... 10z, and the voltage output thereof is the same as the voltage signal conversion means 81 and the A / D conversion means 83 of FIG. From the transmission means 12 having both functions to the monitoring control apparatus 9 via the transmission means 93 of the monitoring control apparatus 9, or the protection measuring devices 8a, 8b, ... 8z of the DC distribution boards 10a, 10b, ... 10z. It transmits to each protection measuring device 8a, 8b, ... 8z via each transmission means 85. FIG.
The generation of power data and power amount data may be the same as the generation in any of the DC switchboard systems of the first and second embodiments described above.

According to the fourth embodiment, it is not necessary to incorporate a voltage sensor in each of the DC switchboards 10a, 10b,... 10z for each branch feeder 3a, 3b,. , 3b,... 3z, all of the plurality of DC distribution boards 10a, 10b,... 10z having no built-in voltage sensor have the same configuration and the same function. In addition, since the monitoring control device 9 is not provided with a master station device, it is possible to reduce the construction cost of a DC switchboard system and a monitor control device including a plurality of DC switchboards.

In the present invention, each embodiment can be appropriately modified or omitted within the scope of the invention.
In addition, in each figure, the same code | symbol shows the same or an equivalent part.

1 AC / DC converter,
3a, 3b, ... 3z branch feeder,
4a, 4b, ... 4z circuit breakers,
5a, 5b, ... 5z DC load,
6 DC voltage sensor,
7a, 7b, ... 7z DC current sensor,
8a, 8b,... 8z protective measuring device,
81 voltage signal conversion means,
82 current signal conversion means,
83 A / D conversion means,
84 computing means,
85 transmission means,
9 Monitoring and control device,
91 Transmission master station,
92 CPU,
93 Transmission means,
10a, 10b, ... 10z DC switchboard,
11 Transmission line,
12 Transmission means.

Claims (8)

In a DC switchboard system comprising a plurality of DC switchboards installed corresponding to each of a plurality of branch feeders branched from a DC bus and connected to a DC load via a circuit breaker, respectively.
One of the plurality of DC distribution boards has a DC voltage sensor for detecting the voltage of the corresponding branch feeder,
All of the plurality of DC distribution boards have a DC current sensor that detects the current of the corresponding branch feeder,
All of the plurality of DC distribution boards have a protective measuring device having a protection function of detecting an abnormality in current and voltage of the corresponding branch feeder and tripping the circuit breaker of the corresponding branch feeder,
Data of the voltage detected by the DC voltage sensor is transmitted to the protective measuring device of the DC switchboard without the DC voltage sensor,
Power used by the DC load of the corresponding branch feeder from the current data and the voltage data detected by the corresponding DC current sensor in all of the protective measuring devices of the plurality of DC distribution boards. And calculate the amount of power,
The data of the electric power and the electric energy calculated by all the protection measurement devices of the plurality of DC distribution boards are transmitted from the protection measurement device to the monitoring control device and used by the DC loads of the plurality of branch feeders. A DC switchboard system characterized in that electric power and electric energy are collectively monitored by the monitoring control device. In the DC switchboard system according to claim 1,
The supervisory control device has a transmission master station, and the voltage data is transmitted from the protection measurement device of the DC switchboard having the DC voltage sensor to the transmission master station,
The voltage data transmitted to the transmission master station is transmitted from the transmission master station to the protection measurement device of the DC switchboard that does not have the DC voltage sensor,
In the protective measuring device of the DC switchboard that does not have the DC voltage sensor, the current of the corresponding branch feeder and the voltage data transmitted from the transmission master station, the corresponding of the branch feeder A DC switchboard system characterized by calculating the electric power and electric energy used by the DC load. In a DC switchboard system comprising a plurality of DC switchboards installed corresponding to each of a plurality of branch feeders branched from a DC bus and connected to a DC load via a circuit breaker, respectively.
One of the plurality of DC distribution boards has a DC voltage sensor for detecting the voltage of the corresponding branch feeder,
All of the plurality of DC distribution boards have a DC current sensor that detects the current of the corresponding branch feeder,
All of the plurality of DC distribution boards have a protective measuring device having a protection function of detecting an abnormality in current and voltage of the corresponding branch feeder and tripping the circuit breaker of the corresponding branch feeder,
Both the voltage data detected by the DC voltage sensor and the current data of each of the plurality of branch feeders detected by the DC current sensor are transmitted to the monitoring control device,
The monitoring and control device calculates the power and the amount of power used by each of the DC loads of the plurality of branch feeders from the current data and the voltage data detected by the DC current sensor,
The power and amount of power used by the DC loads of the plurality of branch feeders are collectively monitored by the monitoring and control device based on the power and power amount data calculated by the monitoring and control device. DC switchboard system. In the DC switchboard system according to claim 3,
The DC distribution board system, wherein the monitoring control device has a transmission master station, and the transmission master station collects the voltage data and the current data of each of the plurality of branch feeders. In a DC switchboard system comprising a plurality of DC switchboards installed corresponding to each of a plurality of branch feeders branched from a DC bus and connected to a DC load via a circuit breaker, respectively.
A DC voltage sensor for detecting the voltage of the DC bus;
All of the plurality of DC distribution boards have a DC current sensor that detects the current of the corresponding branch feeder,
All of the plurality of DC distribution boards have a protective measuring device having a protection function of detecting an abnormality in current and voltage of the corresponding branch feeder and tripping the circuit breaker of the corresponding branch feeder,
Data of the voltage detected by the DC voltage sensor is transmitted to the protective measuring device of the plurality of DC distribution boards,
Power used by the DC load of the corresponding branch feeder from the current data and the voltage data detected by the corresponding DC current sensor in all of the protective measuring devices of the plurality of DC distribution boards. And calculate the amount of power,
The data of the electric power and the electric energy calculated by all the protection measurement devices of the plurality of DC distribution boards are transmitted from the protection measurement device to the monitoring control device and used by the DC loads of the plurality of branch feeders. A DC switchboard system characterized in that electric power and electric energy are collectively monitored by the monitoring control device. In the DC switchboard system according to claim 5,
The supervisory control device has a transmission master station, and the voltage data is transmitted from the DC voltage sensor to the transmission master station,
The voltage data transmitted to the transmission master station is transmitted from the transmission master station to all of the protection measuring devices of the plurality of DC switchboards,
Power and power used by the DC load of the corresponding branch feeder from the current data of the corresponding branch feeder and the data of the voltage transmitted from the transmission master station in all the protective measuring devices. DC switchboard system characterized by calculating quantity. In a DC switchboard system comprising a plurality of DC switchboards installed corresponding to each of a plurality of branch feeders branched from a DC bus and connected to a DC load via a circuit breaker, respectively.
A DC voltage sensor for detecting the voltage of the DC bus;
All of the plurality of DC distribution boards have a DC current sensor that detects the current of the corresponding branch feeder,
All of the plurality of DC distribution boards have a protective measuring device having a protection function of detecting an abnormality in current and voltage of the corresponding branch feeder and tripping the circuit breaker of the corresponding branch feeder,
Both the voltage data detected by the DC voltage sensor and the current data of each of the plurality of branch feeders detected by the DC current sensor are transmitted to the monitoring control device,
The monitoring and control device calculates the power and the amount of power used by each of the DC loads of the plurality of branch feeders from the current data and the voltage data detected by the DC current sensor,
The power and amount of power used by the DC loads of the plurality of branch feeders are collectively monitored by the monitoring and control device based on the power and power amount data calculated by the monitoring and control device. DC switchboard system. In the DC switchboard system according to claim 7,
The DC distribution board system, wherein the monitoring control device has a transmission master station, and the transmission master station collects the voltage data and the current data of each of the plurality of branch feeders.

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