Integration of geomagnetic disturbance modeling into the power flow: A methodology for large-scale system studies

Overbye, Thomas J.; Hutchins, Trevor R.; Shetye, Komal S.; Weber, Judy; Dahman, Scott

doi:10.1109/naps.2012.6336365

Cited by 104 publications

(48 citation statements)

References 10 publications

(21 reference statements)

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“…The model relating substation transformer neutral current to surface electric field is given by (Overbye et al, , ):

I (t) = P G^{- 1} H E (t) = C E (t)

where

I (t) \in {double-struckR}^{T}

are the neutral currents as a function of time t ; T is the number of transformers;

P \in {double-struckR}^{T \times (S + L)}

depends on the transformer configuration (e.g., Y or Δ connected) and resistances; S is the number of substations and L is the number of lines;

G \in {double-struckR}^{(S + L) \times (S + L)}

depends on the topology, line resistances, and substation resistances;

H \in {double-struckR}^{(S + L) \times 2}

depends on the line lengths and orientations; and E ( t ) is the vector of time‐varying northward and eastward surface electric field components. Note that the model makes the simplifying assumption that the induced geoelectric field is uniform over the simulated power grid footprint.…”

Section: Modelsmentioning

confidence: 99%

“…The second modeling step, referred to as the engineering step, involves relating GMD‐driven surface geoelectric field to currents induced in a high‐voltage power network (Albertson et al, ; Boteler & Pirjola, ; Kappenman, ; Overbye et al, ; Pirjola, ). Such models are dependent on knowledge of power grid network topology and other system parameters such as line and substation resistances, transformer configuration, and transformer resistances.…”

Section: Introductionmentioning

confidence: 99%

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Modeling Geomagnetically Induced Currents From Magnetometer Measurements: Spatial Scale Assessed With Reference Measurements

et al. 2017

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Solar‐driven disturbances generate geomagnetically induced currents (GICs) that can result in power grid instability and, in the most extreme cases, even failure. Magnetometers provide direct measurements of the geomagnetic disturbance (GMD) effect on the surface magnetic field and GIC response can be determined from the power grid topology and engineering parameters. This paper considers this chain of models: transforming surface magnetic field disturbance to induced surface electric field through an electromagnetic transfer function and, then, induced surface electric field to GIC using the PowerWorld simulator to model a realistic power grid topology. Comparisons are made to transformer neutral current reference measurements provided by the American Transmission Company. Three GMD intervals are studied, with the Kp index reaching 8− on 2 October 2013, 7 on 1 June 2013, and 6− on 9 October 2013. Ultimately, modeled to measured GIC correlations are analyzed as a function of magnetometer to GIC sensor distance. Results indicate that modeling fidelity during the three studied GMD intervals is strongly dependent on both magnetometer to substation transformer baseline distance and GMD intensity.

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“…The model relating substation transformer neutral current to surface electric field is given by (Overbye et al, , ):

I (t) = P G^{- 1} H E (t) = C E (t)

where

I (t) \in {double-struckR}^{T}

are the neutral currents as a function of time t ; T is the number of transformers;

P \in {double-struckR}^{T \times (S + L)}

depends on the transformer configuration (e.g., Y or Δ connected) and resistances; S is the number of substations and L is the number of lines;

G \in {double-struckR}^{(S + L) \times (S + L)}

depends on the topology, line resistances, and substation resistances;

H \in {double-struckR}^{(S + L) \times 2}

Section: Modelsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Modeling Geomagnetically Induced Currents From Magnetometer Measurements: Spatial Scale Assessed With Reference Measurements

et al. 2017

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“…Several studies assume a linear transformer behavior during GIC saturation (Dong, 2002;Overbye et al, 2012). The increase in reactive power consumption due to saturation caused by GICs is proportional to a coefficient K1 that depends on the characteristics of the transformer core design (Dong, 2002).…”

Section: Transformer Behaviormentioning

confidence: 99%

North Europe power transmission system vulnerability during extreme space weather

Piccinelli

Elisabeth

2018

J. Space Weather Space Clim.

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-Space weather driven by solar activity can induce geomagnetic disturbances at the Earth's surface that can affect power transmission systems. Variations in the geomagnetic field result in geomagnetically induced currents that can enter the system through its grounding connections, saturate transformers and lead to system instability and possibly collapse. This study analyzes the impact of extreme space weather on the northern part of the European power transmission grid for different transformer designs to understand its vulnerability in case of an extreme event. The behavior of the system was analyzed in its operational mode during a severe geomagnetic storm, and mitigation measures, like line compensation, were also considered. These measures change the topology of the system, thus varying the path of geomagnetically induced currents and inducing a local imbalance in the voltage stability superimposed on the grid operational flow. Our analysis shows that the North European power transmission system is fairly robust against extreme space weather events. When considering transformers more vulnerable to geomagnetic storms, only few episodes of instability were found in correspondence with an existing voltage instability due to the underlying system load. The presence of mitigation measures limited the areas of the network in which bus voltage instabilities arise with respect to the system in which mitigation measures are absent.

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“…Applied research efforts have been aimed at understanding the nature of GICs to predict and effectively mitigate them through dynamic control of the grid as an alternative to widespread hardening of transformers. GIC prediction software has been developed to model in near real time the effects within a power system of changes in the electric field at ground level due to GMDs [ Overbye et al ., ; Khosravi and Johansson , ], so that voltages within the system can be biased to lessen harmful effects. The GIC prediction problem reduces the components of the specified grid to an equivalent complex circuit, and it uses the ground electric field along the components of the grid to determine the variable intensity of current flow in response to the imposed electric field [ Pirjola , ].…”

Section: Introductionmentioning

confidence: 99%

Rapid prediction of electric fields associated with geomagnetically induced currents in the presence of three‐dimensional ground structure: Projection of remote magnetic observatory data through magnetotelluric impedance tensors

Bonner

Schultz

2017

Space Weather

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Ground level electric fields arising from geomagnetic disturbances (GMDs) are used by the electric power industry to calculate geomagnetically induced currents (GICs) in the power grid. Current industry practice is limited to electric fields associated with 1‐D ground electrical conductivity structure, yet at any given depth in the crust and mantle lateral (3‐D) variations in conductivity can span at least 3 orders of magnitude, resulting in large deviations in electric fields relative to 1‐D models. Solving Maxwell's equations for electric fields associated with GMDs above a 3‐D Earth is computationally burdensome and currently impractical for industrial applications. A computationally light algorithm is proposed as an alternative. Real‐time data from magnetic observatories are projected through multivariate transfer functions to locations of previously occupied magnetotelluric (MT) stations. MT time series and impedance tensors, such as those publically available from the NSF EarthScope Program, are used to scale the projected magnetic observatory data into local electric field predictions that can then be interpolated onto points along power grid transmission lines to actively improve resilience through GIC modeling. Preliminary electric field predictions are tested against previously recorded time series, idealized transfer function cases, and existing industry methods to assess the validity of the algorithm for potential adoption by the power industry. Some limitations such as long‐period diurnal drift are addressed, and solutions are suggested to further improve the method before direct comparisons with actual GIC measurements are made.

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Integration of geomagnetic disturbance modeling into the power flow: A methodology for large-scale system studies

Cited by 104 publications

References 10 publications

Modeling Geomagnetically Induced Currents From Magnetometer Measurements: Spatial Scale Assessed With Reference Measurements

Modeling Geomagnetically Induced Currents From Magnetometer Measurements: Spatial Scale Assessed With Reference Measurements

North Europe power transmission system vulnerability during extreme space weather

Rapid prediction of electric fields associated with geomagnetically induced currents in the presence of three‐dimensional ground structure: Projection of remote magnetic observatory data through magnetotelluric impedance tensors

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