ExpectedOutcome:Project results are expected to contribute to all of the following expected outcomes:
HVDC technologies contribution achieving climate neutrality of the electricity generation sector allowing the integration of large share of renewables while concurrently addressing the security of supply.HVDC interconnections can act as a firewall blocking the spread of disturbances while permitting the interchange of power.Mastering HVDC technologies will open new business horizons for European companies in the global clean energy markets.Increased electricity system reliability and resilience throughout the overall interconnection system, which includes High Voltage cables. Furthermore, the use of buried HVDC cables reduces the visual impact and improves the social acceptance compared to the classical AC overhead lines.
Scope:Proposals will explore concepts and propose solutions to foster the development of large HVDC based transmission grid infrastructures, able to bring benefits to the existing electrical system and capable of integrating the fore coming large amount of renewable energy.
Proposals should demonstrate the reliability and resilien...
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ExpectedOutcome:Project results are expected to contribute to all of the following expected outcomes:
HVDC technologies contribution achieving climate neutrality of the electricity generation sector allowing the integration of large share of renewables while concurrently addressing the security of supply.HVDC interconnections can act as a firewall blocking the spread of disturbances while permitting the interchange of power.Mastering HVDC technologies will open new business horizons for European companies in the global clean energy markets.Increased electricity system reliability and resilience throughout the overall interconnection system, which includes High Voltage cables. Furthermore, the use of buried HVDC cables reduces the visual impact and improves the social acceptance compared to the classical AC overhead lines.
Scope:Proposals will explore concepts and propose solutions to foster the development of large HVDC based transmission grid infrastructures, able to bring benefits to the existing electrical system and capable of integrating the fore coming large amount of renewable energy.
Proposals should demonstrate the reliability and resilience of the energy system through HVDC interconnections integrated in the AC grid while coping with faster dynamics, in particular by addressing at least two of the following topics:
Proposals of optimal grid architecture concepts using HVDC (e.g. multi terminal, hub operation, etc.) and related demonstrated advantages, with a careful overview of planning aspects and deployment methodologies. Proposals should investigate and identify the technological (e.g. coordination between HVDC converters in close vicinity, modelling of HVDC submarine cables for transient phenomena, etc.), contractual and regulatory barriers for the deployment and present solutions to remove them.Real-time monitoring and assessment of the level of system stability and vulnerability against disturbances of future AC systems characterised by more HVDC and less conventional power generation.Reliability model for HVDC and its impact on the overall transmission system reliability with the HVDC link acting as ‘firewall‘ within the synchronous AC transmission system.Technical-economic benefits of the HVDC interconnection solution with the “firewall” functionality as well as in combination of other advantages contributing to the system security such as relieving heavily loaded AC corridors, etc.Simulation, real time demonstration of the avoidance or containment of cascading effects and resilience to cyberattacks or faults of the HVDC connection in the AC network.Simulation, real time demonstration of the co-ordinated use of HVDC-connected RES for containment of cascading faults and contribution to system restoration.Evaluation of the impact on system reliability of an increasing number of HVDC links incorporated in the transmission system through modelling and quantification of the dynamic “firewall” properties of the HVDC links incorporated in the transmission system.Evaluation of the use of HVAC fault location and monitoring systems for cables in HVDC (e.g. fibre optic distributed temperature sensing, online PD detection and location and time domain reflectometer (TDR) measurements for faults pre-location and fingerprinting).Development of novel pre-fault monitoring systems for the evaluation of the actual status of the HVDC cables and accessories, with the aim to improve the reliability of the DC links.Development and validation of new dielectric materials for the insulation of HVDC cables and accessories aiming at achieving higher capacity transfer capabilities. The proposed materials should have reduced ageing due to space charge accumulation phenomena.Proposals for highly reliable design and manufacturing of HVDC cables and accessories and related demonstrated advantages. Proposals should investigate the sustainability of the identified procedures through LCA. The selected projects are expected to contribute to relevant BRIDGE[1] activities.
Specific Topic Conditions:Activities are expected to achieve TRL 5-6 by the end of the project – see General Annex B.
Cross-cutting Priorities:Social sciences and humanitiesArtificial IntelligenceDigital Agenda
[1]https://www.h2020-bridge.eu/
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