Your search keyword '"Dierk Bormann"' showing total 9 results

1. Localization of mechanical deformations in transformer windings using time-domain representation of response functions

Author

Göran Engdahl, Dierk Bormann, and Hanif Tavakoli

Subjects

Engineering, Frequency response, Frequency response analysis, business.industry, Energy Engineering and Power Technology, Classification of discontinuities, Topology, Electric power transmission, Transformer windings, Modeling and Simulation, Electronic engineering, Time domain, Electrical and Electronic Engineering, Reflectometry, business, Representation (mathematics)

Abstract

Time domain reflectometry (TDR) has been used for localization of discontinuities in transmission lines in diverse applications. In this paper, its potential as an alternative to frequency response ...

Published

2012

2. DC Component From Pantograph Arcing in AC Traction System—Influencing Parameters, Impact, and Mitigation Techniques

Author

Rajeev Thottappillil, Surajit Midya, Dierk Bormann, and Thorsten Schütte

Subjects

Engineering, business.industry, Direct current, Electrical engineering, Power factor, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Automotive engineering, law.invention, Traction power network, law, Harmonics, Power electronics, Electrical network, Pantograph, Electrical and Electronic Engineering, business, DC bias

Abstract

Pantograph arcing in ac traction system generates transients, and causes asymmetries and distortion in supply voltage and current waveforms. These asymmetric voltage and current lead to a net dc component and harmonics that propagate within the traction power and signalling system and cause electromagnetic interference. This problem is enhanced during winter because of the layer of ice/snow on the overhead contact wire. The sliding contact becomes poor and a visible arc moves along with the pantograph. In this paper, it is shown how different parameters like traction current, line speed, power factor, and supply voltage influence the arcing, its characteristics, and the dc components. It is shown that the dc current component increases with increasing train speed and traction current, and reduces at a lower power factor. It is also discussed how the presence of an ice layer influences the arcing and the dc components. It is found that running the trains below the normal operating power factors is an effective choice to mitigate this problem. The findings presented in this paper could be beneficial to estimate the probable limit of the dc component at the planning stage so that proper precautions can be taken at the design stage itself.

Published

2011

3. Pantograph Arcing in Electrified Railways—Mechanism and Influence of Various Parameters—Part I: With DC Traction Power Supply

Author

Rajeev Thottappillil, Dierk Bormann, Thorsten Schütte, and Surajit Midya

Subjects

Engineering, business.industry, Electromagnetic compatibility, Electrical engineering, Energy Engineering and Power Technology, Mechanical engineering, Electromagnetic interference, law.invention, Traction power network, law, EMI, Power electronics, Electrical network, Pantograph, Electrical and Electronic Engineering, business, Overhead line

Abstract

Pantograph arcing is a common phenomenon in electrified railway systems. This is also a source of broadband-conducted and radiated electromagnetic interference (EMI) for vehicle as well as traction power and signaling systems. In this paper and the companion paper, experimental analyses of pantograph arcing phenomena are presented for dc and ac feeding systems, respectively. Influences of different parameters on dc traction system, such as supply-voltage polarity, relative motion between pantograph and overhead contact wire, namely, forward motion along the track (longitudinal), and lateral sliding motion of the pantograph (zigzag) are presented here. From the voltage and current waveforms of the test runs, it is shown that pantograph arcing is a polarity-dependent phenomenon. For the positive-fed overhead traction system, where pantograph is cathode, the supply interruptions due to zigzag motion are comparatively less compared to negatively fed traction systems. As a result, the transients, due to pantograph arcing, are more frequent in negatively fed traction systems. It is found that the arc root movement along the electrode surfaces (pantograph-contact wire) is governed by the relative motion and polarity of the electrodes. The analyses presented in this paper also form a foundation to understand the pantograph arcing process and the corresponding influential parameters with the ac supply presented in the companion paper. The findings presented in this paper could be beneficial for coming up with appropriate mitigation techniques from the EMI due to pantograph arcing in dc-fed traction systems.

Published

2009

4. Repetitive fast voltage stresses-causes and effects

Author

F. Dijkhuizen, Dierk Bormann, F. Sahlen, L. Ming, T. Bengtsson, Ruslan Papazyan, Lars Liljestrand, and M. Dahlgren

Subjects

Engineering, business.industry, Insulation system, Electrical engineering, Electronics, Electrical and Electronic Engineering, Root cause, business, Electronic, Optical and Magnetic Materials, Voltage, Reliability engineering

Abstract

In this article, we have seen how high-frequency system resonances, triggered by power electronic devices, may enhance both electrical and thermal stress on an insulation system. An important lesson from this study is that even an insulation system that is very well designed according to present standards may fail if it is subjected to stresses that were never considered in the design. The root cause of such failures is thus not within the failed part, and it can only be found by studying the entire system where the failed part is used. With the examples given here, we hope that the reader may more easily recognize situations which may warrant a deeper study and perhaps some extra precautions.

Published

2009

5. Vacuum circuit breaker and transformer interaction in a cable system

Author

Dierk Bormann, Lars Liljestrand, Edgar Dullni, Elisabeth Lindell, and Carlos Roy

Subjects

Engineering, Isolation transformer, business.industry, Residual-current device, Electrical engineering, Energy efficient transformer, Isolated-phase bus, Sulfur hexafluoride circuit breaker, business, Distribution transformer, Delta-wye transformer, Circuit breaker

Abstract

Vacuum circuit breakers can cause repetitive transient overvoltages with steep fronts in some cases, depending on the combination of the system configurations and type of circuit breaker operations. Laboratory testing has been performed to improve the understanding of the high frequency system interaction between vacuum circuit breaker, transformer, and cables. A dry type medium voltage transformer has been energized and disconnected in a 20 kV medium voltage laboratory cable system using a vacuum circuit breaker. The transformer is a standard transformer, equipped with additional voltage measuring taps along the disks of one of the high-voltage windings, enabling the measurement of the voltages in the winding when exposed to transient overvoltages. The results show that normal no-load energizing and disconnection of the transformer do not cause any high overvoltages. Disconnection of the transformer with an inductive load or a trip on inrush current during energizing can cause transient overvoltages. Surge arresters, both phases to ground and phase to phase, are recommended for a transformer exposed to these types of circuit breaker operations. (4 pages)

Published

2013

6. Conducted and radiated emission from pantograph arcing in AC traction system

Author

Rajeev Thottappillil, Ziya Mazloom, Dierk Bormann, Surajit Midya, and Thorsten Schütte

Subjects

Engineering, business.industry, medicine.medical_treatment, Acoustics, Electrical engineering, Power factor, Traction (orthopedics), AC power, Electromagnetic interference, Harmonics, medicine, Pantograph, business, Voltage, DC bias

Abstract

One of the most common and yet unavoidable problems in electrified railways are because of pantograph arcing. The intensity of arcing increases during winter because of the ice layer on the overhead contact wire. In AC traction system, pantograph arcing distorts the sinusoidal waveforms of the supply voltage and current. It also generates transients at the current zero crossings (CZC). All these result in a net DC component, harmonics and radiated emission. In this paper we will present an experimental investigation to understand pantograph arcing and influence of power factor on conducted and radiated emission. We found that pantograph arcing generates both conducted and radiated emission in a wide band, starting from DC. Both the DC component and higher order conducted and radiated emission increases with line speed. Running the train at lower power factor can reduce the DC component and emerging as the most preferred solution against problems due to ice in cold weather.

Published

2009

7. Comparison of a simple and a detailed model of magnetic hysteresis with measurements on electrical steel

Author

Hanif Tavakoli, David Ribbenfjärd, Göran Engdahl, and Dierk Bormann

Subjects

Engineering, Mechanical engineering, engineering.material, Electrical Engineering, Electronic Engineering, Information Engineering, Permeability, law.invention, Electromagnetism, law, Electrical machines, Eddy current, Electrical and Electronic Engineering, Elektroteknik och elektronik, business.industry, Eddy currents, Applied Mathematics, Mechanics, Magnetic hysteresis, Computer Science Applications, Magnetic field, Computational Theory and Mathematics, Permeability (electromagnetism), Steel, business, Relative permeability, Electrical steel

Abstract

PurposeFor efficient magnetic field calculations in electrical machines, the hysteresis and losses in laminated electrical steel must be modeled in a simple and reliable way. The purpose of this paper is to investigate and discuss the potential of a simple complex‐permeability model.Design/methodology/approachA frequency dependent complex‐permeability model as well as a more detailed model (describing hysteresis, classical eddy current effects, and excess losses separately) are compared to single‐sheet measurements on laminated electrical steel. It is discussed under which circumstances the simple complex‐μ model is an adequate substitute for the more detailed model.FindingsA satisfactory agreement of the simple complex‐μ model was found with both detailed model and measurements, improving with increasing frequencies. This is true not only for the effective permeability function, but holds also for the detailed H‐B characteristics (hysteresis).Originality/valueIt is demonstrated that the complex‐μ model is a reliable and convenient starting point for the estimation of flux distribution and losses in complicated magnetic core geometries.

Published

2009

8. Understanding pantograph arcing in electrified railways - influence of various parameters

Author

Dierk Bormann, Rajeev Thottappillil, Thorsten Schütte, Anders Larsson, and Surajit Midya

Subjects

Inductance, Electric arc, Engineering, Traction power network, business.industry, Electrical engineering, Electromagnetic compatibility, Mechanical engineering, Pantograph, Waveform, business, Electrical contacts, Voltage

Abstract

The most common and yet unavoidable EMC problems with electrified railways are due to pantograph arcing. This distorts the waveform of the supply voltage and current, can generates transients during the zero crossings of the current and can cause interference with the traction power and signalling system. Pantograph arcing is a complex phenomenon and depends on speed of the train, current, presence of inductance etc. In a sliding contact like pantograph and contact wire, the arc root moves across both electrodes because of the relative motion between them. In this paper, we will present an experimental analyses of the arc root movement and influence of different parameters on it using a laboratory setup.

Published

2008

9. DC components in pantograph arcing: mechanisms and influence of various parameters

Author

Surajit Midya, Rajeev Thottappillil, and Dierk Bormann

Subjects

Engineering, Electrical load, business.industry, Electrical engineering, Track circuit, law.invention, law, Power electronics, Harmonics, Pantograph, business, Transformer, DC bias, Voltage

Abstract

Pantograph arcing generates a net DC voltage which create interference with the track circuit signaling, saturate transformer core, generate even harmonics, create problems on control of the switching of power electronics and drives. Experiments were conducted by Bombardier Transportation and ABB as a part of the ICE project to understand the physical processes that generates this DC component, the coupling mechanisms and the distribution paths, the identification of DC vulnerable components and their response to this DC. The amplitude of the DC voltage shows a wide variation with respect to applied voltage, train speed, type of electrical load, gap between the contact wire and the pantograph and current. In this paper, the authors analyzed those experimental data to understand the typical nature of sliding arc between the pantograph and the contact wire and possible mechanisms involved with this.

Published

2007