Your search keyword '"A. Starflinger"' showing total 8 results

1. Recent numerical simulations and experiments on coolability of debris beds during severe accidents of light water reactors.

Author

Starflinger, J., Buck, M., Hartmann, A., Kulenovic, R., Leininger, S., Rahman, S., and Rashid, M.

Subjects

*LIGHT water reactors, *HYDRAULICS, *NUMERICAL analysis, *COMPUTER simulation, *PREDICTION models

Abstract

In the course of a severe accident in light water reactors with core degradation, so-called debris beds can be formed inside the reactor pressure vessel or in the reactor cavity. The strategy to analyse the coolability of such debris beds with both experiments and numerical simulations is discussed. The numerical simulations are carried out with MEWA (MElt WAter) code, being developed at the institute for the prediction of the thermal-hydraulic conditions inside a debris bed, including the prediction of dryout heat flux. The simulations show good agreement with experimental data of the DEBRIS experiments. [ABSTRACT FROM AUTHOR]

Published

2015

2. European supercritical water cooled reactor

Author

Schulenberg, T., Starflinger, J., Marsault, P., Bittermann, D., Maráczy, C., Laurien, E., Lycklama à Nijeholt, J.A., Anglart, H., Andreani, M., Ruzickova, M., and Toivonen, A.

Subjects

*WATER cooled reactors, *PRESSURE vessels, *THERMAL neutrons, *COMPUTATIONAL fluid dynamics, *SUPERCRITICAL fluids, *LOW pressure (Science), *HIGH pressure (Science)

Abstract

Abstract: The High Performance Light Water Reactor (HPLWR), how the European Supercritical Water Cooled Reactor is called, is a pressure vessel type reactor operated with supercritical water at 25MPa feedwater pressure and 500°C average core outlet temperature. It is designed and analyzed by a European consortium of 10 partners and 3 active supporters from 8 Euratom member states in the second phase of the HPLWR project. Most emphasis has been laid on a core with a thermal neutron spectrum, consisting of small fuel assemblies in boxes with 40 fuel pins each and a central water box to improve the neutron moderation despite the low coolant density. Peak cladding temperatures of the fuel rods have been minimized by heating up the coolant in three steps with intermediate coolant mixing. The containment design with its safety and residual heat removal systems is based on the latest boiling water reactor concept, but with different passive high pressure coolant injection systems to cause a forced convection through the core. The design concept of the steam cycle is indicating the envisaged efficiency increase to around 44%. Moreover, it provides the constraints to design the components of the balance of the plant. The project is accompanied by numerical studies of heat transfer of supercritical water in fuel assemblies and by material tests of candidate cladding alloys, performed by the consortium and supported by additional tests of the Joint Research Centre of the European Commission. Besides the scientific and technical progress, the HPLWR project turned out to be most successful in training the young generation of nuclear engineers in the technologies of light water reactors. More than 20 bachelor or master theses and more than 10 doctoral theses on HPLWR technologies have been submitted at partner organizations of this consortium since the start of this project. [Copyright &y& Elsevier]

Published

2011

3. Development of a coupled neutronic/thermal-hydraulic tool with multi-scale capabilities and applications to HPLWR core analysis

Author

Monti, Lanfranco, Starflinger, Jörg, and Schulenberg, Thomas

Subjects

*LIGHT water reactors, *HYDRAULIC engineering, *MULTISCALE modeling, *NUCLEAR reactor cores, *NUCLEAR reactor cooling, *NUCLEAR reactor design & construction, *NEUTRON transport theory, *NEUTRONS spectra

Abstract

Abstract: The High Performance Light Water Reactor (HPLWR) is a thermal spectrum nuclear reactor cooled and moderated with light water operated at supercritical pressure. It is an innovative reactor concept, which requires developing and applying advanced analysis tools as described in the paper. The relevant water density reduction associated with the heat-up, together with the multi-pass core design, results in a pronounced coupling between neutronic and thermal-hydraulic analyses, which takes into account the strong natural influence of the in-core distribution of power generation and water properties. The neutron flux gradients within the multi-pass core, together with the pronounced dependence of water properties on the temperature, require to consider a fine spatial resolution in which the individual fuel pins are resolved to provide precise evaluation of the clad temperature, currently considered as one of the crucial design criteria. These goals have been achieved considering an advanced analysis method based on the usage of existing codes which have been coupled with developed interfaces. Initially neutronic and thermal-hydraulic full core calculations have been iterated until a consistent solution is found to determine the steady state full power condition of the HPLWR core. Results of few group neutronic analyses might be less reliable in case of HPLWR 3-pass core than for conventional LWRs because of considerable changes of the neutron spectrum within the core, hence 40 groups transport theory has been preferred to the usual 2 groups diffusion theory. Successively, with the usage of a developed pin-power reconstruction technique capable to account for the innovative fuel assembly design, sub-channel investigations of the individual fuel assemblies have been performed evaluating pin-wise clad temperatures. Obtained results will be discussed giving a detailed insight of the revolutionary HPLWR 3 pass core concept and understanding the physical reasons, which influence the local clad temperatures. The obtained results represent a new quality in core analyses, which takes into full consideration the coupling between neutronics and thermal-hydraulics as well as the spatial effects of the fuel assembly heterogeneity in determining the local pin-power and the associated maximum clad temperature. [Copyright &y& Elsevier]

Published

2011

4. Mixing of cooling water in the mixing chambers of the HPLWR—High Performance Light Water Reactor

Author

Wank, Alexander, Starflinger, Jörg, Schulenberg, Thomas, and Laurien, Eckart

Subjects

*LIGHT water reactors, *NUCLEAR reactor cooling, *PERFORMANCE evaluation, *SUPERCRITICAL fluids, *EVAPORATORS, *COMPUTATIONAL fluid dynamics

Abstract

Abstract: The High Performance Light Water Reactor (HPLWR), a supercritical water cooled reactor concept with multiple heat-up steps, requires efficient mixing of the coolant between these steps to minimize hot spots in the core. Analyzing and improving the mixing in the mixing chamber above the core, situated between evaporator and superheater assemblies, and below the core, between the first and second superheater, is one of the challenges in the design process of the HPLWR. Different measures to enhance mixing have been studied with CFD analyses, in which a new design approach has been applied to the upper mixing chamber. It simplifies the complex structures and takes the effects of the disregarded structures into account by introducing source terms into the momentum equations. [ABSTRACT FROM AUTHOR]

Published

2010

5. Towards strategic agenda for European nuclear education, training, and knowledge management.

Author

Cizelj, Leon, Pesznyák, Csilla, Starflinger, Jörg, Pavel, Gabriel Lazaro, Wastin, Franck, and Michailidou, Eirini

Subjects

*KNOWLEDGE management, *NUCLEAR warfare, *HUMAN resources departments, *SUSTAINABILITY

Abstract

[Display omitted] • Key elements of the Europe-wide strategic agenda for nuclear education, training, and knowledge management proposed. • Urgent and sustainable strategic support, coordination, and partnership between all nuclear stakeholders, is needed. • Challenges in attraction, development and retaining of nuclear talents are discussed. The key elements of the EU-wide strategic agenda for nuclear education, training, and knowledge management are proposed in this paper. They were developed partly within the ENEN+ and ENEN# projects, to support and consolidate the efforts of the nuclear stakeholders to attract, develop, and retain new talents. The paper considers the projections of needs developed by the European Human Resources Observatory-Nuclear (EHRO-N). It builds on the existing national nuclear education strategies in the EU and beyond and more than two decades of experience with the European Nuclear Education Network (ENEN). The paper outlines and substantiates the most important actions and risks related to human resources, which need to be managed successfully for the EU to contribute to the tripling of the nuclear power generation capacity on the planet by 2050 (as announced in COP28) and to retain its leading role in the nuclear power and non-power applications. The sheer complexity of this challenge calls for high-level strategic support, coordination, and partnership between all nuclear stakeholders, especially those involved in the decision-making. The present situation calls for urgent strategic actions with long-term sustainability. [ABSTRACT FROM AUTHOR]

Published

2024

6. Concept of a pressurized water reactor cooled with supercritical water in the primary loop

Author

Vogt, B., Fischer, K., Starflinger, J., Laurien, E., and Schulenberg, T.

Subjects

*PRESSURIZED water reactors, *SUPERCRITICAL fluids, *ENERGY consumption, *PRESSURE vessels, *TEMPERATURE effect, *HYDRAULIC engineering

Abstract

Abstract: A novel concept of a pressurized water reactor with a primary loop cooled with supercritical water is introduced and analyzed in this work. A steam cycle analysis has been performed to illustrate the advantages of such a nuclear power plant with respect to specific power and thermal efficiency. Moreover, a reactor pressure vessel concept including its internals and a suitable core and fuel assembly design are presented overcoming the problems, which arise due to the high heat up of the coolant and the density change involved with it. The core power and coolant density distributions are predicted with coupled neutronic and thermal-hydraulic analyses. The method features the definition of inlet orifices for coolant mass flow adjustment within the core as well as an additional tool for the interpolation of local pin power data. The latter one has been used for a successive sub-channel analysis of the hottest fuel assembly of the core, which provides a more detailed spatial resolution and thus predicts peak cladding temperatures, the maximum linear pin power of fuel pins, and maximum fuel temperatures. It can be shown that maximum temperatures of claddings and fuel are well below the material limits. Thanks to an average core exit temperature below the pseudo-critical temperature, the core concept leaves enough margin for additional uncertainties and allowances for operation. [ABSTRACT FROM AUTHOR]

Published

2010

7. Fuel assembly design study for a reactor with supercritical water

Author

Hofmeister, J., Waata, C., Starflinger, J., Schulenberg, T., and Laurien, E.

Subjects

*FUEL, *NUCLEAR reactors, *LIGHT water reactors, *ELECTRIC power production

Abstract

Abstract: The European concept of the High Performance Light Water Reactor (HPLWR) differs from current light water reactors in a higher system pressure beyond the critical point of water, as well as a higher heat-up of the coolant within the core and thus higher core outlet temperatures, leading to a significant increase in turbine power and thermal efficiency of the power plant. The motivation to develop a novel fuel assembly for the HPLWR is caused by the high variation of coolant density in the core by more than a factor of seven. A systematic design study shows that a square fuel assembly with two rows of fuel rods and a central moderator box is best to minimize the structural material, to optimize the moderator to fuel ratio and to reduce differences of fuel rod power. Using neutronic and thermal-hydraulic analyses, a detailed mechanical design of a fuel assembly of the HPLWR has been worked out. Moreover, concepts for the head piece, the foot piece, the steam plenum and the lower mixing plenum, including the lower core plate, have been developed to account for the individual flow paths of this reactor. These allow a leak-tight counter current flow of moderator water and coolant as well as uniform mixing of different mass flows. The assembly design concept can be used as a general key component for any advanced core design of this reactor. [Copyright &y& Elsevier]

Published

2007

8. The ENEN's role in shaping the European nuclear education.

Author

Lazaro Pavel, Gabriel, Pesznyak, Csilla, Javier Elorza Tenreiro, Francisco, Starflinger, Joerg, Cizelj, Leon, and Ambrosini, Walter

Subjects

*NUCLEAR energy, *UNIVERSITIES & colleges, *INTERNATIONAL agencies, *NUCLEAR science, *NUCLEAR shapes

Abstract

• History of ENEN in support to nuclear knowledge communities. • Biggest nuclear Education and Training Organization in Europe. • European Commission funded education. • Networking among Universities and Research Centers. • Novel technologies in Nuclear. The European Nuclear Education Network (ENEN) just celebrated in 2023 the first twenty years of existence. During this period, the ENEN network grew, reaching today more than ninety Members, Partners and Supporters. The mission of ENEN is the preservation and the further development of expertise in the nuclear fields by higher Education and Training. We target to reach this objective through the co-operation between universities, research organisations, regulatory bodies, the industry and any other organisations involved in the application of nuclear science and ionising radiation. Networking is an important method that we use to achieve success in our actions. Either if we speak about networking between people that aim at delivering specific education and training (E&T) actions (attraction to nuclear, higher education and training, workshops, webinars, summer/winter schools, etc.) or networking between persons who need an upgrade in their professional career through these E&T actions, we strongly believe that collaboration is the answer for a safe usage of nuclear energy in Europe and beyond. Today, ENEN is the response to the European need for highly educated people in the nuclear field by meeting these needs through cooperation between industry, research centers, technical support organizations international organizations and higher education institutions. This paper summarizes the recent evolution of ENEN after twenty years of existence and the vision for the coming period, in the service of nuclear education in Europe. [ABSTRACT FROM AUTHOR]

Published

2024