Your search keyword '"Pavel Purgat"' showing total 9 results

1. Low-Voltage dc System Building Blocks: Integrated Power Flow Control and Short Circuit Protection

Author

Zian Qin, Aditya Shekhar, Pavel Purgat, and Pavol Bauer

Subjects

Power flow, System building, business.industry, Computer science, Control (management), Electrical engineering, Short circuit protection, Electrical and Electronic Engineering, business, Low voltage, Industrial and Manufacturing Engineering

Published

2023

2. Protection Framework for Low Voltage DC Grids

Author

Pavol Bauer, Matthijs T. J. Spaan, Nils H. van der Blij, Laura Ramirez-Elizondo, Pavel Purgat, and Thiago Batista Soeiro

Subjects

Computer science, business.industry, 020209 energy, 020208 electrical & electronic engineering, Solid-state, Electrical engineering, Hardware_PERFORMANCEANDRELIABILITY, 02 engineering and technology, Limiting, Fault (power engineering), Inductor, Power electronics, 0202 electrical engineering, electronic engineering, information engineering, Electric potential, business, Low voltage, Circuit breaker

Abstract

This paper presents a protection framework for low voltage dc grids, which segments these grids into zones and tiers according to their fault current potential and provided protection. Furthermore, the technology and applications of different protection devices are examined. It is demonstrated that the utilization of fast fault interruption and fault limiting inductors are vital for the protection of low voltage dc grids. Moreover, a design of a solid-state circuit breaker is presented, and this devices is experimentally verified. The experimental results showed that the total time for the detection and interruption of faults can be lower than $1 \mu \mathrm{s}$ with solid-state protection devices.

Published

2021

3. Design criteria of solid-state circuit breaker for low-voltage microgrids

Author

Nils H. van der Blij, Zian Qin, Samad Shah, Pavel Purgat, and Pavol Bauer

Subjects

Flowchart, TK7800-8360, Computer science, 020209 energy, 020208 electrical & electronic engineering, Solid state circuit breaker, Direct current, 02 engineering and technology, Fault detection and isolation, law.invention, Reliability engineering, Safe operation, law, 0202 electrical engineering, electronic engineering, information engineering, Key (cryptography), Sensitivity (control systems), Electronics, Electrical and Electronic Engineering, Low voltage

Abstract

Solid‐state circuit breakers (SSCB) show great promise to become the key element in the protection of low‐voltage direct current microgrids. SSCBs operate in the microsecond range and employ semi‐conductor devices that have strict safe operation area limits. Therefore, the design of the SSCB needs to consider the effects of fault detection delays and semi‐conductor safe operation area limitations. This paper derives SSCB design criteria that consider the effect of different detection methods with different detection delays under varying system constraints. The design space is investigated in a sensitivity analysis, which provides insights into the operation boundaries of SSCB and explains how a combination of fault detection methods can reduce the SSCB size. The insights from the theoretical and sensitivity analysis are used to propose an SSCB design flowchart. SSCB prototype is developed and tested in different scenarios under nominal grid voltage and current. The derived design constraints can be used for efficient SSCB design and also to evaluate the effects of different protection schemes on the required SSCB size.

Published

2021

4. Decentralized Plug-and-Play Protection Scheme for Low Voltage DC Grids

Author

Nils H. van der Blij, Laura Ramirez-Elizondo, Matthijs T. J. Spaan, Pavol Bauer, Pavel Purgat, and Thiago Batista Soeiro

Subjects

Control and Optimization, lcsh:T, fault analysis, Renewable Energy, Sustainability and the Environment, Plug and play, business.industry, Computer science, Electrical engineering, Energy Engineering and Power Technology, Topology (electrical circuits), Fault (power engineering), lcsh:Technology, Fault detection and isolation, decentralized protection scheme, plug-and-play systems, low voltage direct current grids, Electrical and Electronic Engineering, business, solid-state circuit breakers, Engineering (miscellaneous), Low voltage, Circuit breaker, Energy (miscellaneous), Voltage

Abstract

Since the voltages and currents in dc grids do not have a natural zero-crossing, the protection of these grids is more challenging than the protection of conventional ac grids. Literature presents several unit and non-unit protection schemes that rely on communication, or knowledge about the system&rsquo, s topology and parameters in order to achieve selective protection in these grids. However, communication complicates fast fault detection and interruption, and a system&rsquo, s parameters are subject to uncertainty and change. This paper demonstrates that, in low voltage dc grids, faults propagate fast through the grid and interrupted inductive currents commutate to non-faulted sections of the grid, which both can cause circuit breakers in non-faulted sections to trip. A decentralized plug-and-play protection scheme is proposed that ensures selectivity via an augmented solid-state circuit breaker topology and by utilizing the proposed time-current characteristic. It is experimentally shown that the proposed scheme provides secure and selective fault interruption for radial and meshed low voltage dc grids under various conditions.

Published

2020

5. Partially Rated Power Flow Control Converter Modeling for Low Voltage DC Grids

Author

Zian Qin, Nils H. van der Blij, Pavol Bauer, and Pavel Purgat

Subjects

Flow control (data), Direct current, Computer science, 020209 energy, 020208 electrical & electronic engineering, Energy Engineering and Power Technology, Topology (electrical circuits), modeling, 02 engineering and technology, Inductor, Grid, power flow control, microgrid, Power rating, Power electronics, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, low voltage, Microgrid, Electrical and Electronic Engineering, Low voltage

Abstract

Scalable and robust low-voltage direct current (LVdc) distribution networks require solutions, allowing flexible power flow control and reliable short-circuit protection. In this paper, the continuous full-order large-and small-signal models of a partially rated power flow control converter (PFCC) are derived utilizing the generalized averaging method. The large-signal model of the PFCC is coupled with a model of the LVdc grid. Due to the state-space representation, the combined model of the PFCC and the LVdc grid is suitable for easy algorithmization, and efficient simulation. These advantages make them essential tools for studying and optimizing of scalable LVdc systems with decentralized power flow control based on the PFCC. The PFCC models provide insights into controller design and stability analysis. The models are experimentally validated, and the functionality of the PFCC is demonstrated in a laboratory-scale microgrid.

Published

2019

6. On the Protection of the Power Flow Control Converter in Meshed Low Voltage DC Networks

Author

Zian Qin, Pavel Purgat, Laurens Mackay, and Pavol Bauer

Subjects

business.industry, Computer science, 020209 energy, Control (management), Electrical engineering, 02 engineering and technology, Converters, Grid, Power flow, Power rating, 0202 electrical engineering, electronic engineering, information engineering, business, Low voltage, Galvanic isolation, Circuit breaker

Abstract

The two main challenges of meshed low voltage DC grids today are the flexible control of power flow and the short-circuit protection. The conventional approach to deal with both problems is to incorporate galvanically isolated DC-DC converters with integrated short-circuit protection, which are rated for the full power rating of the grid. In this paper, we describe an approach based on the combination of a converter which has a partial power rating with respect to the grids power rating and a circuit breaker with full rating with respect to the grid. Based on the review of abnormal operating conditions of the power flow control converter and its requirements on protection. We propose a new protection strategy for the power flow control converter and evaluate the applicable circuit breaker technologies based on the review of the protection requirements.

Published

2018

7. Design of a Power Flow Control Converter for Bipolar Meshed LVDC Distribution Grids

Author

Yunchao Han, Zian Qin, Pavol Bauer, Laurens Mackay, Matthias Schulz, Martin Marz, and Pavel Purgat

Subjects

Computer science, 020209 energy, 020208 electrical & electronic engineering, Direct current, Topology (electrical circuits), 02 engineering and technology, Grid, Power (physics), law.invention, Capacitor, Power rating, law, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Low voltage, Power control

Abstract

Flexible power flow control is one of the main challenges in the development of the meshed low voltage direct current distribution system. The most widely adopted approach to achieve flexible power control in the network is to use various solid-state based solutions which are rated for the peak power of the grid. In this paper, we propose a solution based on a converter which has several times smaller power rating than the grid power rating. Due to the multi-port nature of the proposed solution, it is well suited for the bipolar networks.

Published

2018

8. A partially rated DC-DC converter for power flow control in meshed LVDC distribution grids

Author

Zian Qin, Pavol Bauer, Ryan Adilardi Prakoso, Laura Ramirez-Elizondo, Laurens Mackay, and Pavel Purgat

Subjects

Flow control (data), Computer science, business.industry, 020209 energy, Control (management), Electrical engineering, 02 engineering and technology, Converters, Grid, Controllability, Power rating, 0202 electrical engineering, electronic engineering, information engineering, Current (fluid), business, Low voltage

Abstract

In meshed low voltage DC distribution grids, one of the main challenges is achieving controllability of the power flow. The most common approach to achieve the full control over the power flow in the meshed DC grid is to deploy DC-DC converters rated for the full power rating of the grid. The drawbacks of this solution are costs and losses of such DC-DC converters. To reduce the costs and the losses from the system standpoint, we introduce a partially rated power flow control converter. This paper presents the control modes of the partially rated power flow control converter and experimentally demonstrates its functionality. The proposed power flow control converter consists of two cascaded converters. On one side the converter is rated for the maximum grid voltage but only a fraction of the grid current, and on the other side, it is rated for the maximum grid current but only a fraction of the grid voltage. The proposed converter can operate in three modes and demonstrates the power flow control capability.

Published

2018

9. Modularity in power electronics: Conceptualization, classification and outlook

Author

Pavol Bauer, Jelena Gerber-Popovic, and Pavel Purgat

Subjects

Computer science, business.industry, 020209 energy, 020208 electrical & electronic engineering, 02 engineering and technology, Modular design, Renewable energy, Power electronics, 0202 electrical engineering, electronic engineering, information engineering, Systems engineering, Redundancy (engineering), Electronics, business, Low voltage

Abstract

Increased proliferation of the renewable energy sources (RES) brings more power electronic devices to the power distribution. Modularity on the converter level is one of the key concepts enabling flexibility, scalability and high availability of the new solutions for the distribution networks(e.g. for low voltage DC). To understand the trends and performance trade-offs it is important to describe and classify different aspects of the modularity concept. This paper presents a comprehensive literature review, classification of modular power electronics and outlook on future research. Different aspects of modularity are identified and described from the perspective of a converter designer, manufacturer and a user. It is illustrated that depending on a combination of different aspects, different modules are selected resulting in different technical challenges. These aspect can be considered as a mapping tool for the functional description and physical realization of the power converter.

Published

2017