Towards electrothermal optimization of a hvdc cable joint based on field simulation

Yvonne Späck-Leigsnering; M. Greta Ruppert; Erion Gjonaj; Herbert De Gersem; Myriam Koch

doi:10.3390/en14102848

Towards electrothermal optimization of a hvdc cable joint based on field simulation

Yvonne Späck-Leigsnering, M. Greta Ruppert, Erion Gjonaj, Herbert De Gersem, Myriam Koch

Associate Professorship of High Voltage Engineering and Switchgear Technology

Technische Universität Darmstadt

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Extruded high-voltage direct current cable systems transmit electric power over long distances. Numerical field simulation can provide access to the internal electrothermal behavior of cable joints, which interconnect cable sections. However, coupled nonlinear electrothermal field simulations are still a challenge. In this work, a robust numerical solution approach is implemented and validated. This approach allows for efficient parameter studies of resistively graded high-voltage direct current cable joint designs. It is assessed how the dielectric stress distribution between the conductor connection and the grounded cable sheath is influenced by nonlinear field and temperature dependent electric conductivity of the field grading material. Optimal field grading material parameters, which fulfill the field grading and power loss requirements, are suggested based on the simulation studies.

Original language	English
Article number	2848
Journal	Energies
Volume	14
Issue number	10
DOIs	https://doi.org/10.3390/en14102848
State	Published - 2 May 2021

Keywords

Field grading
HVDC
Joints
Multiphysics
Nonlinear electrothermal coupling
Power cables

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.3390/en14102848

Cite this

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title = "Towards electrothermal optimization of a hvdc cable joint based on field simulation",

abstract = "Extruded high-voltage direct current cable systems transmit electric power over long distances. Numerical field simulation can provide access to the internal electrothermal behavior of cable joints, which interconnect cable sections. However, coupled nonlinear electrothermal field simulations are still a challenge. In this work, a robust numerical solution approach is implemented and validated. This approach allows for efficient parameter studies of resistively graded high-voltage direct current cable joint designs. It is assessed how the dielectric stress distribution between the conductor connection and the grounded cable sheath is influenced by nonlinear field and temperature dependent electric conductivity of the field grading material. Optimal field grading material parameters, which fulfill the field grading and power loss requirements, are suggested based on the simulation studies.",

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AU - Späck-Leigsnering, Yvonne

AU - Ruppert, M. Greta

AU - Gjonaj, Erion

AU - De Gersem, Herbert

AU - Koch, Myriam

PY - 2021/5/2

Y1 - 2021/5/2

N2 - Extruded high-voltage direct current cable systems transmit electric power over long distances. Numerical field simulation can provide access to the internal electrothermal behavior of cable joints, which interconnect cable sections. However, coupled nonlinear electrothermal field simulations are still a challenge. In this work, a robust numerical solution approach is implemented and validated. This approach allows for efficient parameter studies of resistively graded high-voltage direct current cable joint designs. It is assessed how the dielectric stress distribution between the conductor connection and the grounded cable sheath is influenced by nonlinear field and temperature dependent electric conductivity of the field grading material. Optimal field grading material parameters, which fulfill the field grading and power loss requirements, are suggested based on the simulation studies.

AB - Extruded high-voltage direct current cable systems transmit electric power over long distances. Numerical field simulation can provide access to the internal electrothermal behavior of cable joints, which interconnect cable sections. However, coupled nonlinear electrothermal field simulations are still a challenge. In this work, a robust numerical solution approach is implemented and validated. This approach allows for efficient parameter studies of resistively graded high-voltage direct current cable joint designs. It is assessed how the dielectric stress distribution between the conductor connection and the grounded cable sheath is influenced by nonlinear field and temperature dependent electric conductivity of the field grading material. Optimal field grading material parameters, which fulfill the field grading and power loss requirements, are suggested based on the simulation studies.

KW - Field grading

KW - HVDC

KW - Joints

KW - Multiphysics

KW - Nonlinear electrothermal coupling

KW - Power cables

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Towards electrothermal optimization of a hvdc cable joint based on field simulation

Abstract

Keywords

UN SDGs

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