KR20210048204A - Method and apparatus for high voltage direct current system - Google Patents

Abstract

Disclosed are a signal transmission/reception method and a device for HVDC system. According to an embodiment of the present invention, a signal transmission/reception method includes the steps of: receiving a plurality of first optical signals converted so that a plurality of control signals for controlling each of a plurality of sub-modules each have a unique optical wavelength; generating a second optical signal by combining the plurality of first optical signals; transmitting the second optical signal; receiving the second optical signal and branching the second optical signal into the plurality of first optical signals according to the unique optical wavelength; and transmitting the plurality of first optical signals to the plurality of sub-modules. According to the present invention, high-speed and reliable data transmission/reception for the HVDC system is possible.

Description

Signal transmission/reception method and apparatus for HVDC system {METHOD AND APPARATUS FOR HIGH VOLTAGE DIRECT CURRENT SYSTEM}

The following embodiments relate to a method and apparatus for transmitting and receiving signals for an HVDC system.

The High Voltage Direct Current (HDVC) system is a system that converts AC power produced by a power plant into DC and transmits it in order to minimize power loss that occurs when transmitting large amounts of power. HVDC systems can be classified into current type and voltage type according to the power semiconductor devices used in the converter station.

MMC (Modular Multi-level Converter)-based voltage type HVDC system using IGBT (Insulated Gate Bipolar Transistor) valve reduces installation area and facilitates voltage control compared to current type HVDC system using thyristor valve. Accordingly, the demand for voltage-type HVDC systems is increasing in recent years. However, in the voltage-type HVDC system, the number of installed sub-modules increases as the power transmission capacity increases. When the number of sub-modules of the voltage-type HVDC system increases, the initial equipment cost increases due to an increase in the number of communication ports and cables, and becomes inefficient in terms of network maintenance.

Accordingly, it is necessary to develop a technology that enables high-speed and reliable data transmission/reception in the voltage-type HVDC system and at the same time reducing the cost of a cable for data transmission and reception and maintenance costs.

The embodiments convert a plurality of control signals into a plurality of optical signals having a unique optical wavelength, and transmit the plurality of optical signals as a combined optical signal, thereby enabling high-speed and reliable data transmission and reception for an HVDC system. It is possible to provide a technology capable of reducing the cost of cables and maintenance costs for data transmission and reception.

A signal transmission/reception method according to an embodiment includes the steps of receiving a plurality of first optical signals converted so that a plurality of control signals for controlling each of a plurality of sub-modules each have a unique optical wavelength, and the plurality of second optical signals 1 combining optical signals to generate a second optical signal, transmitting the second optical signal, and receiving the second optical signal to receive the second optical signal according to a unique optical wavelength. And branching into one optical signal, and transmitting the plurality of first optical signals to the plurality of sub-modules.

Each of the plurality of first optical signals is transmitted to any one of a plurality of first optical modules included in a control device for controlling the plurality of sub-modules, and each has a different unique optical wavelength. It may have been transformed to have.

The plurality of first optical signals may be converted into the plurality of control signals through a second optical module included in each of the plurality of sub-modules and transmitted to the plurality of sub-modules.

The signal transmission/reception method according to the embodiment includes the steps of receiving a plurality of third optical signals converted so that a plurality of sensing data acquired by the plurality of sub-modules each have a unique optical wavelength, and the plurality of third optical signals The method may further include combining the optical signals to generate a fourth optical signal, and transmitting the fourth optical signal.

The plurality of third optical signals may be a set of optical signals in which sensing data generated by each of the plurality of sub-modules is converted to each have a unique optical wavelength through the second optical module.

The signal transmission/reception method according to the embodiment includes the steps of receiving the fourth optical signal, branching the fourth optical signal into the plurality of third optical signals according to a unique optical wavelength, and the plurality of It may further include transmitting third optical signals to a control device that controls the plurality of sub-modules.

The plurality of third optical signals may be converted into a plurality of sensing data through a plurality of first optical modules included in the control device and transmitted to the control device.

A signal transmission/reception method according to another embodiment includes a time division multiplexing (TDM) through a first optical module and a second optical module in which a control signal for controlling a plurality of sub-modules is connected to a control device for controlling a plurality of sub-modules. Receiving the first optical signal converted in the) method, and transmitting the first optical signal to any one of the plurality of sub-modules.

The signal transmission/reception method according to another embodiment includes a time division multiplexing (TDM) through a third optical module and a fourth optical module to which a plurality of sensing data acquired by the plurality of sub-modules are connected to each of the plurality of sub-modules. The method may further include receiving a plurality of second optical signals converted in the) method, and transmitting the plurality of second optical signals to a control device for controlling the plurality of sub-modules.

Each of the plurality of second optical signals may be transmitted according to a time allocated to each of the plurality of sub-modules.

A signal transmission/reception apparatus according to an embodiment receives a plurality of first optical signals converted so that a plurality of control signals for controlling each of a plurality of sub-modules each have a unique optical wavelength, and receives the plurality of first optical signals. A first MUX/DEMUX for generating a second optical signal by combining signals and transmitting the second optical signal, and receiving the second optical signal, and receiving the second optical signal, the plurality of And a second MUX/DEMUX branching into first optical signals and transmitting the plurality of first optical signals to the plurality of sub-modules.

Each of the plurality of first optical signals is transmitted to any one of a plurality of first optical modules included in a control device for controlling the plurality of sub-modules, and each has a different unique optical wavelength. It may have been transformed to have.

The plurality of first optical signals may be converted into the plurality of control signals through a second optical module included in each of the plurality of sub-modules and transmitted to the plurality of sub-modules.

The second MUX/DEMUX receives a plurality of third optical signals converted so that a plurality of sensing data acquired by the plurality of sub-modules each have a unique optical wavelength, and combines the plurality of third optical signals. A fourth optical signal may be generated and the fourth optical signal may be transmitted.

The plurality of third optical signals may be a set of optical signals in which sensing data generated by each of the plurality of sub-modules is converted to each have a unique optical wavelength through the second optical module.

The first MUX/DEMUX receives the fourth optical signal, divides the fourth optical signal into the plurality of third optical signals according to a unique optical wavelength, and divides the plurality of third optical signals into the plurality of It can be transmitted to the control device that controls the sub-modules of.

The plurality of third optical signals may be converted into a plurality of sensing data through a plurality of first optical modules included in the control device and transmitted to the control device.

A signal transmission/reception apparatus according to another embodiment includes a first optical module connected to a control device for controlling a plurality of sub-modules, and a first optical splitter and a second optical splitter connected to each of a transmission end of the second optical module. And a first signal transmitting/receiving device, wherein each of the first optical splitter and the second optical splitter receives a control signal for controlling the plurality of sub-modules through the first optical module and the second optical module. A first optical signal converted by a TDM (Time Division Multiplexing) method is received, and the first optical signal is transmitted to any one of the plurality of sub-modules.

The signal transmission/reception apparatus according to another exemplary embodiment includes a third optical splitter and a fourth optical splitter connected to each of a receiving end of a first optical module and a second optical module connected to a control device for controlling a plurality of sub-modules. Including a second signal transmitting and receiving device comprising a, wherein each of the third optical splitter and the fourth optical splitter, the plurality of sensing data obtained by the plurality of sub-modules are connected to each of the plurality of sub-modules A plurality of second optical signals converted by a time division multiplexing (TDM) method may be received through the optical module and the fourth optical module, and the plurality of second optical signals may be transmitted to the control device.

Each of the plurality of second optical signals may be transmitted according to a time allocated to each of the plurality of sub-modules.

1 is a diagram illustrating a sub-module control network used in an existing HVDC system.
2 is a diagram showing a control network of an EtherCAT-based daisy-chain structure widely used in the industrial network field.
3 is a diagram showing an HVDC system according to an embodiment.
4 and 5 are flowcharts illustrating the overall operation of the HVDC system shown in FIG. 3.
6 is a diagram showing an HVDC system according to another embodiment.
7 is a diagram for explaining the overall operation of the HVDC system shown in FIG. 6.
9 and 10 are diagrams for explaining the operation of the sub-module.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. However, since various changes may be made to the embodiments, the scope of the patent application is not limited or limited by these embodiments. It is to be understood that all changes, equivalents, or substitutes to the embodiments are included in the scope of the rights.

The terms used in the examples are used for illustrative purposes only and should not be construed as limiting. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present specification, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof does not preclude in advance.

Terms such as first or second may be used to describe various elements, but the elements should not be limited by terms. The terms are only for the purpose of distinguishing one component from other components, for example, without departing from the scope of rights according to the concept of the embodiment, the first component may be named as the second component, and similarly The second component may also be referred to as a first component.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the embodiment belongs. Terms as defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in the present application. Does not.

In addition, in the description with reference to the accompanying drawings, the same reference numerals are assigned to the same components regardless of the reference numerals, and redundant descriptions thereof will be omitted. In describing the embodiments, when it is determined that a detailed description of related known technologies may unnecessarily obscure the subject matter of the embodiments, the detailed description thereof will be omitted.

A module in the present specification may mean hardware capable of performing functions and operations according to each name described in the present specification, or may mean a computer program code capable of performing a specific function and operation. Or, it may mean an electronic recording medium, for example, a processor or a microprocessor in which a computer program code capable of performing a specific function and operation is mounted.

In other words, a module may mean a functional and/or structural combination of hardware for performing the technical idea of the present invention and/or software for driving the hardware.

1 is a diagram illustrating a sub-module control network used in an existing HVDC system, and FIG. 2 is a diagram illustrating an EtherCAT-based daisy-chain structure control network widely used in the industrial network field.

In the MMC-HVDC (Modular Multi level Converter-High Voltage Direct Current) converter station 10, the central control unit (CA 1) and the sub-modules (SM1-1 to SM 1-N) are point-to-point (P2P). ) Exchange data through a topology-based communication network.

However, when a point-to-point topology-based communication network is configured in the MMC-HVDC converter station 10 for large-capacity power transmission, initial equipment cost is high due to an increase in the number of communication ports and cables of the central control unit CA 1. Accordingly, the MMC-HVDC converter station 10 is inefficient in terms of network maintenance, and facility expansion according to an increase in facility capacity is also not easy.

In the case of the control network 20 based on EtherCAT (Ethernet for Control Automation Technology), compared to the MMC-HVDC converter station 10, the number of communication ports of the central control unit (CA 2) and communication link requirements can be reduced compared to the network. have.

However, in the case of the EtherCAT-based control network 20, the EtherCAT dedicated chip for “on-the-fly” processing in which the network node reads the data passing through the frame is a sub-module (SM 2-1 to SM 2-N). ) Is necessary. In addition, since the EtherCAT-based control network 20 uses a daisy-chain network structure, when two or more failures among the sub-modules SM 2-1 to SM 2-N occur, a failure occurs in the entire communication.

Embodiments can provide a communication system capable of high-speed and reliable data transmission and reception in a voltage-type HVDC system and at the same time reducing cable requirements.

In addition, embodiments provide a communication method that enables high-speed information exchange with high reliability of a control signal of a control device and various sensing data measured in a plurality of sub-modules in a voltage-type HVDC system composed of a plurality of sub-modules. can do.

3 is a diagram showing an HVDC system according to an embodiment.

The HVDC system 10 includes a control device 100, a signal transmission/reception device 200, and a plurality of sub-modules 300.

The HVDC system 10 may convert a plurality of signals into a plurality of optical signals having a unique optical wavelength, combine the plurality of optical signals, and transmit a single optical signal. The HVDC system 10 enables high-speed and reliable data transmission and reception, and at the same time, it is possible to reduce the cost of a cable for data transmission and reception and maintenance costs.

The HVDC system 10 may reduce the number of optical cores by transmitting an optical signal in which a plurality of signals are allocated to different wavelengths to one optical fiber. The HVDC system 10 can reduce cables for communication. The HVDC system 10 is easy to expand the facility according to an increase in facility capacity without the need for an extension of an intermediate line.

The control device 100 may transmit a plurality of control signals for controlling an Insulated-Gate Bipolar Transistor (IGBT) of each of the plurality of submodules 300 to the plurality of submodules 300.

The control device 100 may include a controller 110 and a plurality of first optical modules 130.

The controller 110 may generate a plurality of control signals. The controller 110 may transmit a plurality of control signals to the plurality of first optical modules 130. For example, the controller 110 may transmit each of the plurality of control signals to any one (one of 130-1 to 130-n), each of the plurality of first optical modules 130.

The plurality of first optical modules 130 may convert a plurality of control signals into a plurality of first optical signals each having a unique optical wavelength. For example, any one 130-1 of the plurality of first optical modules 130 may receive any one of the plurality of control signals and convert it into an optical signal having a first optical wavelength. The other one 130-2 of the plurality of first optical modules 130 may receive the other one of the plurality of control signals and convert it into an optical signal having a second optical wavelength. That is, the plurality of control signals converted by the plurality of first optical modules 130 may all be converted into a plurality of first optical signals having different unique optical wavelengths.

The plurality of first optical modules 130 may transmit a plurality of first optical signals to the signal transmission/reception device 200.

The plurality of first optical modules 130 may receive a plurality of third optical signals from the signal transmission/reception device 200. The plurality of first optical modules 130 may convert a plurality of third optical signals into a plurality of sensing data. The plurality of first optical modules 130 may transmit a plurality of sensing data to the controller 110.

The signal transmission/reception apparatus 200 may combine a plurality of optical signals each having a unique optical wavelength and transmit the combined optical signal as one optical signal. The signal transmission/reception apparatus 200 may branch one optical signal into a plurality of optical signals each having a unique optical wavelength.

The signal transmission/reception apparatus 200 may include a first MUX/DEMUX 210 and a second MUX/DEMUX 250.

The first MUX/DEMUX 210 may receive a plurality of first optical signals. For example, the first MUX/DEMUX 210 may receive any one of a plurality of first optical signals from any one 130-1 of the plurality of first optical modules 130. The first MUX/DEMUX 210 may receive another one of the plurality of first optical signals from the other one 130-2 of the plurality of first optical modules 130.

The first MUX/DEMUX 210 may generate a second optical signal by combining a plurality of first optical signals. For example, the second optical signal may be one optical signal. The second optical signal may store each of the plurality of first optical signals according to a unique optical wavelength of each of the plurality of first optical signals.

The first MUX/DEMUX 210 may transmit a second optical signal to the second MUX/DEMUX 250. For example, the first MUX/DEMUX 210 may transmit the second optical signal to the second MUX/DEMUX 250 through a single mode fiber (SF).

The first MUX/DEMUX 210 may receive a fourth optical signal from the second MUX/DEMUX 250. The first MUX/DEMUX 210 may branch the fourth optical signal into a plurality of third optical signals according to a unique optical wavelength.

The first MUX/DEMUX 210 may transmit a plurality of third optical signals to the control device 100.

The second MUX/DEMUX 250 may receive the second optical signal and divide the second optical signal into a plurality of first optical signals according to a unique optical wavelength.

The second MUX/DEMUX 250 may transmit a plurality of first optical signals to the plurality of sub-modules 300.

The second MUX/DEMUX 250 may receive a plurality of third optical signals converted so that the plurality of sensing data acquired by the plurality of sub-modules 300 each have a unique optical wavelength.

The second MUX/DEMUX 250 may generate a fourth optical signal by combining a plurality of third optical signals. For example, the fourth optical signal may be one optical signal. The fourth optical signal may store each of the plurality of third optical signals according to a unique optical wavelength of each of the plurality of third optical signals.

The second MUX/DEMUX 250 may transmit the fourth optical signal to the first MUX/DEMUX 210. For example, the second MUX/DEMUX 250 may transmit the fourth optical signal to the first MUX/DEMUX through a single mode fiber (SF).

The plurality of sub-modules 300 may include a first sub-module 300-1, a second sub-module 300-2 to an n-th sub-module 300-n. The plurality of sub-modules 300 may include a plurality of second optical modules 310. That is, the sub-modules 300-1 to 300-n may each include the second optical modules 310-1 to 310-n.

The second optical modules 310-1 to 310 -n may convert a plurality of first optical signals into a plurality of control signals, respectively. The second optical modules 310-1 to 310-n may transmit a plurality of control signals to the submodules 300-1 to 300-n.

The plurality of submodules 300 may acquire a plurality of sensing data. The sub-modules 300-1 to 300-n may transmit a plurality of sensing data to the second optical modules 310-1 to 310-n, respectively.

The plurality of submodules 300 may convert a plurality of sensing data into a plurality of third optical signals and transmit them to the second MUX/DEMUX 250. For example, the plurality of submodules 300 may transmit a plurality of sensing data in a burst format.

The second optical modules 310-1 to 310-n may convert a plurality of sensing data into a plurality of third optical signals to each have a unique optical wavelength. For example, a plurality of third optical signals are converted so that sensing data generated by each of the plurality of sub-modules 300 have their own optical wavelengths through the second optical modules 310-1 to 310-n. It may be a set of optical signals.

The second optical modules 310-1 to 310 -n may transmit a plurality of third optical signals to the second MUX/DEMUX 250.

4 and 5 are flowcharts illustrating the overall operation of the HVDC system shown in FIG. 3.

4 is a flowchart illustrating a process in which a plurality of control signals are transmitted from the control device 100 to the plurality of sub-modules 300.

The controller 110 may generate a plurality of control signals. The controller 110 may transmit a plurality of control signals to the plurality of first optical modules 130 (1110 ).

The plurality of first optical modules 130 may convert a plurality of control signals into a plurality of first optical signals each having a unique optical wavelength. The plurality of first optical modules 130 may transmit a plurality of first optical signals to the first MUX/DEMUX 210 (1120 ).

The first MUX/DEMUX 210 may generate a second optical signal by combining a plurality of first optical signals. The first MUX/DEMUX 210 may transmit a second optical signal to the second MUX/DEMUX 250 (1130).

The second MUX/DEMUX 250 may branch the second optical signal into a plurality of first optical signals according to a unique optical wavelength. The second MUX/DEMUX 250 may transmit a plurality of first optical signals to the plurality of second optical modules 310 (1140 ).

The plurality of second optical modules 310 may convert a plurality of first optical signals into a plurality of control signals, respectively. The plurality of second optical modules 310 may transmit a plurality of control signals to each of the plurality of sub-modules 300 (1150).

5 is a flowchart illustrating a process in which sensing data is transmitted from the plurality of submodules 300 to the control device 100.

The plurality of submodules 300 may acquire a plurality of sensing data. The plurality of sub-modules 300 may transmit a plurality of sensing data to the plurality of second optical modules 310 (1510).

The plurality of second optical modules 310 may convert a plurality of sensing data into a plurality of third optical signals to each have a unique optical wavelength. The plurality of second optical modules 310 may transmit a plurality of third optical signals to the second MUX/DEMUX 250 (1520 ).

The second MUX/DEMUX 250 may generate a fourth optical signal by combining a plurality of third optical signals. The second MUX/DEMUX 250 may transmit the fourth optical signal to the first MUX/DEMUX 210 (1530).

The first MUX/DEMUX 210 may branch the fourth optical signal into a plurality of third optical signals according to a unique optical wavelength. The first MUX/DEMUX 210 may transmit a plurality of third optical signals to the plurality of first optical modules 130 (1540 ).

The plurality of first optical modules 130 may convert a plurality of third optical signals into a plurality of sensing data, respectively. The plurality of first optical modules 130 may transmit a plurality of sensing data to the controller 110 (1550 ).

6 is a diagram showing an HVDC system according to another embodiment.

The HVDC system 10 includes a control device 100, a plurality of sub-modules 300, a first signal transmission/reception device 400, and a second signal transmission/reception device 500.

The HVDC system 10 may transmit a plurality of signals by duplexing a plurality of signals using a Time Division Multiplexing (TDM) method, and may receive and distribute a plurality of signals in an integrated manner. The HVDC system 10 enables high-speed and reliable data transmission and reception, and at the same time, it is possible to reduce the cost of a cable for data transmission and reception, and maintenance costs.

The control device 100 may transmit a plurality of control signals for controlling an Insulated-Gate Bipolar Transistor (IGBT) of each of the plurality of submodules 300 to the plurality of submodules 300.

The control device 100 may include a controller 110, a first optical module 150, and a second optical module 170. For example, the first optical module 150 may be a main transmission/reception module of the control device 100. The second optical module 170 may be a secondary transmission/reception module of the control device 100. The control device 100 may duplicate signals through the first optical module 150 and the second optical module 170. The first optical module 150 and the second optical module 170 may transmit a downlink signal using a broadcasting method. The first optical module 150 and the second optical module 170 may transmit an uplink signal using a burst method. In the case of an uplink signal, the first optical module 150 and the second optical module 170 may transmit signals at allotted times in order to avoid collisions between signals.

The controller 110 may generate a control signal. The controller 110 may transmit a control signal to the first optical module 150 and/or the second optical module 170.

The first optical module 150 and the second optical module 170 may generate a first optical signal by converting a control signal into a time division multiplexing (TDM) method.

The first optical module 150 and the second optical module 170 may transmit a first optical signal to the first signal transmission/reception device 400. For example, the first optical module 150 may transmit a first optical signal to the first optical splitter 410. The second optical module 170 may transmit the first optical signal to the second optical splitter 430.

The plurality of submodules 300 may acquire a plurality of sensing data. The plurality of sub-modules 300 may generate a plurality of second optical signals by converting a plurality of sensing data using a time division multiplexing (TDM) method. The plurality of second optical signals may have the same optical wavelength.

The plurality of sub-modules 300 transmits each of the plurality of second optical signals to the second signal transmission/reception apparatus 400 according to a time allocated for each of the sub-modules 300-1, 300-2, 300-3 to 300-n. ), respectively.

The plurality of sub-modules 300 may include a third optical module 350 and a fourth optical module 370. For example, the third optical module 350 may be a main transmission/reception module of the plurality of sub-modules 300. The fourth optical module 370 may be a sub-transmitting/receiving module of the plurality of sub-modules 300. The plurality of sub-modules 300 may duplicate signals through the third optical module 350 and the fourth optical module 370. The third optical module 350 and the fourth optical module 370 may transmit a downlink signal using a broadcasting method. The third optical module 350 and the fourth optical module 370 may transmit an uplink signal using a burst method. In the case of an uplink signal, the third optical module 350 and the fourth optical module 370 may transmit signals at allotted times in order to avoid collisions between signals.

The sub-modules 300-1 to 300-n may transmit sensing data to the third optical module 350 or the fourth optical module 370.

The third optical module 350 and the fourth optical module 370 may generate a second optical signal by converting sensing data using a time division multiplexing (TDM) method.

The third optical module 350 and the fourth optical module 370 may transmit a second optical signal to the second signal transmission/reception device 500. For example, the third optical module 350 may transmit the second optical signal to the third optical splitter 510. The fourth optical module 470 may transmit the second optical signal to the fourth optical splitter 530.

The first signal transmission/reception device 400 may receive a first optical signal. The first signal transmission/reception apparatus 400 may transmit the first optical signal to any one of the plurality of sub-modules 300.

The first signal transmission/reception device 400 may include a first optical splitter 410 and a second optical splitter 430.

The first optical splitter 410 may be connected to the transmission terminal P1.TX of the first optical module 150. The first optical splitter 410 may receive a first optical signal. The first optical splitter 410 may transmit the first optical signal to any one of the plurality of sub-modules 300.

The second optical splitter 430 may be connected to the transmission terminal P2.TX of the second optical module 170. The second optical splitter 430 may receive a first optical signal. The second optical splitter 430 may transmit the first optical signal to any one of the plurality of sub-modules 300.

The second signal transmission/reception device 500 may receive a plurality of second optical signals. The second signal transmission/reception device 500 may transmit a plurality of second optical signals to the control device 100.

The second signal transmission/reception device 500 may include a third optical splitter 510 and a fourth optical splitter 530.

The third optical splitter 510 may be connected to correspond to the receiving end P1.RX of the first optical module 150. The third optical splitter 510 may receive a plurality of second optical signals. The third optical splitter 510 may transmit a plurality of second optical signals to the control device 100. For example, the third optical splitter 510 may transmit a plurality of second optical signals to the receiving end P1.RX of the first optical module 150.

The fourth optical splitter 530 may be connected to correspond to the receiving end P2.RX of the second optical module 170. The fourth optical splitter 530 may receive a plurality of second optical signals. The fourth optical splitter 530 may transmit a plurality of second optical signals to the control device 100. For example, the fourth optical splitter 530 may transmit a plurality of second optical signals to the receiving end P2.RX of the second optical module 170.

7 is a diagram for explaining the overall operation of the HVDC system shown in FIG. 6.

7 is a flowchart illustrating a process in which a control signal is transmitted from the control device 100 to the plurality of submodules 300.

The controller 110 may generate a control signal. The controller 110 may transmit a control signal to the first optical module 150 and/or the second optical module 170 (2110 ).

The first optical module 150 and the second optical module 170 may generate a first optical signal by converting a control signal into a time division multiplexing (TDM) method. The first optical module 150 and the second optical module 170 may transmit the first optical signal by duplexing it to the first signal transmitting/receiving device 400 (2120 ).

The first signal transmission/reception device 400 may receive a first optical signal. The first signal transmission/reception apparatus 400 may transmit the first optical signal to any one of the plurality of sub-modules 300.

8 is a flowchart illustrating a process in which a plurality of sensing data is transmitted from the plurality of submodules 300 to the control device 100.

The plurality of submodules 300 may acquire a plurality of sensing data. The plurality of submodules 300 may transmit a plurality of sensing data to the third optical module 350 or the fourth optical module 370 (2510 ).

The third optical module 350 and the fourth optical module 370 may generate a plurality of second optical signals by converting a plurality of sensing data using a time division multiplexing (TDM) method.

The third optical module 350 and the fourth optical module 370 transmit each of the plurality of second optical signals according to the time allocated for each of the sub-modules 300-1, 300-2, 300-3 to 300-n. Each of the second signal transmission/reception devices 400 may be transmitted (2520).

The second signal transmission/reception device 400 may receive a plurality of second optical signals. The second signal transmission/reception device 400 may transmit a plurality of second optical signals to the control device 100 (2530).

9 and 10 are diagrams for explaining the operation of the sub-module.

9 is a diagram showing a schematic block diagram of the sub-module 300-1, and FIG. 8 is a diagram illustrating a signal transmission method according to a packet transmission period for each sub-module.

For convenience of description, only the submodule 300-1, which is one of the plurality of submodules 300, will be described. However, the remaining sub-modules 300-2 to 300-n have the same configuration as the sub-module 300-1 and may perform the same operation.

The sub-module 300-1 includes a signal receiving unit 320-1, a signal collecting unit 330-1, an IGBT control unit 340-1, an address setting unit 350-1, an address recognition unit 360-1, and A delay setting unit 370-1, a transmission control unit 380-1, and a signal transmission unit 390-1 may be included.

The signal receiver 320-1 may receive a downlink signal. The IGBT control unit 340-1 may receive a downlink signal from the signal receiving unit 320-1 and control an IGBT corresponding to the downlink signal.

The address setting unit 350-1 may be a physical switch. The address recognition unit 360-1 may define an address based on address information from a physical switch.

The delay setting unit 370-1 may transmit an uplink signal at a predetermined allocation time as shown in FIG. 10 according to the defined address information.

The method according to the embodiment may be implemented in the form of program instructions that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like alone or in combination. The program instructions recorded on the medium may be specially designed and configured for the embodiment, or may be known and usable to those skilled in computer software. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic media such as floptical disks. -A hardware device specially configured to store and execute program instructions such as magneto-optical media, and ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those produced by a compiler, but also high-level language codes that can be executed by a computer using an interpreter or the like. The hardware device described above may be configured to operate as one or more software modules to perform the operation of the embodiment, and vice versa.

The software may include a computer program, code, instructions, or a combination of one or more of these, configuring the processing unit to operate as desired or processed independently or collectively. You can command the device. Software and/or data may be interpreted by a processing device or, to provide instructions or data to a processing device, of any type of machine, component, physical device, virtual equipment, computer storage medium or device. , Or may be permanently or temporarily embodyed in a transmitted signal wave. The software may be distributed over networked computer systems and stored or executed in a distributed manner. Software and data may be stored on one or more computer-readable recording media.

As described above, although the embodiments have been described by the limited drawings, a person of ordinary skill in the art can apply various technical modifications and variations based on the above. For example, the described techniques are performed in a different order from the described method, and/or components such as systems, structures, devices, circuits, etc. described are combined or combined in a form different from the described method, or other components Alternatively, even if substituted or substituted by an equivalent, an appropriate result can be achieved.

Therefore, other implementations, other embodiments, and claims and equivalents fall within the scope of the following claims.

Claims (20)

Receiving a plurality of first optical signals converted so that a plurality of control signals for controlling each of the plurality of sub-modules each have a unique optical wavelength;
Generating a second optical signal by combining the plurality of first optical signals;
Transmitting the second optical signal;
Receiving the second optical signal and dividing the second optical signal into the plurality of first optical signals according to a unique optical wavelength; And
And transmitting the plurality of first optical signals to the plurality of sub-modules.
The method of claim 1,
The plurality of first optical signals,
Each of the plurality of control signals is transmitted to any one of a plurality of first optical modules included in a control device for controlling the plurality of sub-modules and converted to have different unique optical wavelengths.
Signal transmission and reception method for HVDC system.
The method of claim 1,
The plurality of first optical signals,
The plurality of control signals are converted into the plurality of control signals through a second optical module included in each of the plurality of sub-modules and transmitted to the plurality of sub-modules.
Signal transmission and reception method for HVDC system.
The method of claim 1,
Receiving a plurality of third optical signals converted so that the plurality of sensing data acquired by the plurality of sub-modules each have a unique optical wavelength;
Generating a fourth optical signal by combining the plurality of third optical signals; And
Transmitting the fourth optical signal
Signal transmission and reception method for the HVDC system further comprising a.
The method of claim 4,
The plurality of third optical signals,
The sensing data generated by each of the plurality of sub-modules is a set of optical signals converted to each have a unique optical wavelength through the second optical module.
Signal transmission and reception method for HVDC system.
The method of claim 4,
Receiving the fourth optical signal;
Branching the fourth optical signal into the plurality of third optical signals according to a unique optical wavelength; And
Transmitting the plurality of third optical signals to a control device that controls the plurality of sub-modules
Signal transmission and reception method for the HVDC system further comprising a.
The method of claim 6,
The plurality of third optical signals,
Converted into a plurality of sensing data through a plurality of first optical modules included in the control device and transmitted to the control device
Signal transmission and reception method for HVDC system.
A control signal for controlling a plurality of sub-modules transmits a first optical signal converted by a Time Division Multiplexing (TDM) method through a first optical module and a second optical module connected to a control device for controlling a plurality of sub-modules. Receiving; And
Transmitting the first optical signal to any one of the plurality of sub-modules
Signal transmission and reception method for an HVDC system comprising a.
The method of claim 8,
A plurality of second optical signals converted by a time division multiplexing (TDM) method through a third optical module and a fourth optical module in which a plurality of sensing data acquired by the plurality of sub-modules are connected to each of the plurality of sub-modules Receiving them; And
Transmitting the plurality of second optical signals to a control device for controlling the plurality of sub-modules
Signal transmission and reception method for the HVDC system further comprising a.
The method of claim 9,
Each of the plurality of second optical signals is transmitted according to an allotted time for each of the plurality of sub-modules.
Signal transmission and reception method for HVDC system.
Receives a plurality of first optical signals converted so that a plurality of control signals for controlling each of a plurality of sub-modules each have a unique optical wavelength, and generates a second optical signal by combining the plurality of first optical signals And a first MUX/DEMUX for transmitting the second optical signal; And
A second optical signal receiving the second optical signal, dividing the second optical signal into the plurality of first optical signals according to a unique optical wavelength, and transmitting the plurality of first optical signals to the plurality of sub-modules 2 MUX/DEMUX
Signal transmitting and receiving device for an HVDC system comprising a.
The method of claim 11,
The plurality of first optical signals,
Each of the plurality of control signals is transmitted to any one of a plurality of first optical modules included in a control device for controlling the plurality of sub-modules and converted to have different unique optical wavelengths.
Signal transmitting and receiving device for HVDC system.
The method of claim 11,
The plurality of first optical signals,
The plurality of control signals are converted into the plurality of control signals through a second optical module included in each of the plurality of sub-modules and transmitted to the plurality of sub-modules.
Signal transmitting and receiving device for HVDC system.
The method of claim 11,
The second MUX/DEMUX,
Receiving a plurality of third optical signals converted so that the plurality of sensing data acquired by the plurality of sub-modules each have a unique optical wavelength, and generating a fourth optical signal by combining the plurality of third optical signals, Transmitting the fourth optical signal
Signal transmitting and receiving device for HVDC system.
The method of claim 14,
The plurality of third optical signals,
The sensing data generated by each of the plurality of sub-modules is a set of optical signals converted to each have a unique optical wavelength through the second optical module.
Signal transmitting and receiving device for HVDC system.
The method of claim 14,
The first MUX/DEMUX,
Control device for receiving the fourth optical signal, branching the fourth optical signal into the plurality of third optical signals according to a unique optical wavelength, and controlling the plurality of sub-modules with the plurality of third optical signals Transferred to
Signal transmitting and receiving device for HVDC system.
The method of claim 16,
The plurality of third optical signals,
Converted into a plurality of sensing data through a plurality of first optical modules included in the control device and transmitted to the control device
Signal transmitting and receiving device for HVDC system.
A first signal transmission/reception device including a first optical splitter and a second optical splitter connected to respective transmission ends of a first optical module and a second optical module connected to a control device for controlling a plurality of sub-modules
Including,
Each of the first light splitter and the second light splitter,
A control signal for controlling the plurality of sub-modules receives a first optical signal converted by a Time Division Multiplexing (TDM) method through the first optical module and the second optical module, and the first optical signal is transmitted to the first optical module. A signal transmission/reception device for an HVDC system that transmits to any one of a plurality of submodules.
The method of claim 18,
A second signal transmitting/receiving device including a third optical splitter and a fourth optical splitter connected to respective receiving ends of a first optical module and a second optical module connected to a control device for controlling a plurality of sub-modules
Including,
Each of the third light splitter and the fourth light splitter,
A plurality of second optical signals converted by a time division multiplexing (TDM) method through a third optical module and a fourth optical module in which a plurality of sensing data acquired by the plurality of sub-modules are connected to each of the plurality of sub-modules And transmitting the plurality of second optical signals to the control device
Signal transmitting and receiving device for HVDC system.
The method of claim 19,
Each of the plurality of second optical signals is transmitted according to an allotted time for each of the plurality of sub-modules.
Signal transmitting and receiving device for HVDC system.

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