Control device in HVDC system and operating method of thereof

What is claimed is: 1. A control device for a high voltage direct current (HVDC) system, the control device comprising: a communication unit configured to perform communication with a component in the HVDC system; and a control unit configured to: control the communication unit to receive, from the component, data on an available state of the component, and calculate an availability of the HVDC system defined as a ratio of an actual operation time of the HVDC system to an operable time of the HVDC system based on data on the available state of the component, wherein the actual operation time of the HVDC system is defined as a time excluding an inoperable time of the HVDC system from the operable time of the HVDC system, wherein the inoperable time of the HVDC system is defined as a time for which the HVDC system does not normally operate for inoperable reasons though the HVDC system is in an operable state, and a planned stop time is not included in the inoperable time of the HVDC system, wherein the planned stop time is a time that has been scheduled to stop for system maintenance and a component check upon a construction of the HVDC system. 2. The control device according to claim 1 , wherein the control unit performs control of the HVDC system based on the data on the available state of the component and the availability of the HVDC system. 3. The control device according to claim 1 , wherein the inoperable reasons comprise at least one of maintenance, a defect, or a system backup or update. 4. The control device according to claim 1 , wherein the operable time of the HVDC system is a time requested by a customer upon construction of a system. 5. The control device according to claim 1 , further comprising a storage unit, wherein the control unit stores the data on the available state of the component and the availability of the HVDC system in the storage unit. 6. The control device according to claim 1 , wherein the control unit checks the component at the planned stop time for which the HVDC system does not operate, in a case where the availability of the HVDC system is lower than a desired value. 7. The control device according to claim 1 , wherein in a case where the HVDC system transmits power as a bipolar transmission signal, the control unit checks a component connected to one side of the bipolar transmission signal at a time when the power moves to another side of the bipolar transmission signal in a case where the availability of the HVDC system is lower than a desired value. 8. The control device according to claim 1 , wherein the control unit adds, to the HVDC system, at least one of an alternating current (AC) harmonic filter, a DC smoothing reactor, a reactive power compensator, and a gas insulated switchgear (GIS) without stopping an operation of the HVDC system, in a case where the availability of the HVDC system is lower than a desired value. 9. The control device according to claim 1 , wherein the component comprises at least one of a current transformer, a potential transformer, a thyristor valve, a reactive power compensator, a GIS, an AC harmonic filter, a converter transformer, a DC smoothing reactor, a disconnected switch, an earth switch (ES), and a DC transmission line. 10. The control device according to claim 1 , wherein the control unit assigns a priority or weight to the component based on at least one of whether or how much the component affects an operation of the HVDC system. 11. An HVDC system comprising: at least one component related to an operation of the HVDC system; and a control device configured to: perform communication with the component to receive data on an available state of the component, calculate availability of the HVDC system that is defined as a ratio of an actual operation time of the HVDC system to an operable time of the HVDC system, based on the data on the available state of the component, and perform control of the HVDC system based on the data on the available state of the component and the availability of the HVDC system, wherein the actual operation time of the HVDC system is defined as a time excluding an inoperable time of the HVDC system from the operable time of the HVDC system, wherein the inoperable time of the HVDC system is defined as a time for which the HVDC system does not normally operate for inoperable reasons though the HVDC system is in an operable state, and a planned stop time is not included in the inoperable time of the HVDC system, wherein the planned stop time is a time that has been scheduled to stop for system maintenance and a component check upon a construction of the HVDC system. 12. A method of operating a control device for an HVDC system, the method comprising: performing communication with a component in the HVDC system to receive data on an available state of the component; calculating availability of the HVDC system that is defined as a ratio of an actual operation time of the HVDC system to an operable time of the HVDC system, based on the data on the available state of the component; and performing control of the HVDC system based on the data on the available state of the component and the availability of the HVDC system, wherein the actual operation time of the HVDC system is defined as a time excluding an inoperable time of the HVDC system from the operable time of the HVDC system, wherein the inoperable time of the HVDC system is defined as a time for which the HVDC system does not normally operate for inoperable reasons though the HVDC system is in an operable state, and a planned stop time is not included in the inoperable time of the HVDC system, wherein the planned stop time is a time that has been scheduled to stop for system maintenance and a component check upon a construction of the HVDC system. 13. The method according to claim 12 , wherein the operable time of the HVDC system is a time requested by a customer upon construction of a system. 14. The method according to claim 12 , wherein the data on the available state of the component and the availability of the HVDC system are stored. 15. The method according to claim 12 , wherein the component is checked at the planned stop time for which the HVDC system does not operate, in a case where the availability of the HVDC system is lower than a desired value. 16. The method according to claim 12 , wherein in a case where the HVDC system transmits power as a bipolar transmission signal, a component connected to one side of the bipolar transmission signal is checked at a time when the power moves to another side of the bipolar transmission signal in a case where the availability of the HVDC system is lower than a desired value. 17. The method according to claim 12 , wherein at least one of an AC harmonic filter, a DC smoothing reactor, a reactive power compensator, and a GIS is added to the HVDC system without stopping an operation of the HVDC system, in a case where the availability of the HVDC system is lower than a desired value.