Design and verification of a hermetic high-speed turbogenerator concept for biomass and waste heat recovery applications
Grönman, Aki; Nerg, Janne; Sikanen, Eerik; Sillanpää, Teemu; Nevaranta, Niko; Scherman, Eero; Uusitalo, Antti; Uzhegov, Nikita; Smirnov, Alexander; Honkatukia, Juha; Sallinen, Petri; Jastrzebski, Rafal; Heikkinen, Janne; Backman, Jari; Pyrhönen, Juha; Pyrhönen, Olli; Sopanen, Jussi; Turunen-Saaresti, Teemu (2020-09-11)
Post-print / Final draft
Grönman, Aki
Nerg, Janne
Sikanen, Eerik
Sillanpää, Teemu
Nevaranta, Niko
Scherman, Eero
Uusitalo, Antti
Uzhegov, Nikita
Smirnov, Alexander
Honkatukia, Juha
Sallinen, Petri
Jastrzebski, Rafal
Heikkinen, Janne
Backman, Jari
Pyrhönen, Juha
Pyrhönen, Olli
Sopanen, Jussi
Turunen-Saaresti, Teemu
11.09.2020
Energy Conversion and Management
225
Elsevier
School of Energy Systems
Julkaisun pysyvä osoite on
https://urn.fi/URN:NBN:fi-fe2020091669628
https://urn.fi/URN:NBN:fi-fe2020091669628
Tiivistelmä
Many waste heat recovery and biomass applications offer opportunities for small-scale steam turbines to produce electricity and to improve systems’ energy efficiency. However, the currently used axial turbine-based technology is generally characterized by a relatively large physical size and poor design and off-design performances. To overcome these challenges, a new compact water-cooled high-speed radial outflow turbine concept is proposed. While the previous understanding of the chosen novel rotor water cooling approach indicates general system feasibility, improved turbine performance, and good potential, the scientific literature lacks relevant information. Since the design of high-speed machines is always case-dependent, every concept must be verified. Hence, to provide verification and new scientific information, this study combines analytical, numerical, and experimental analyses. The results predict turbine performance levels comparable with the previous radial outflow design, and its efficiency was found to exceed those of conventional turbines. During the experiments, the turbine also produced electricity from poor-quality steam, and its rotor dynamic behavior and magnetic bearing performance were close to the predicted results. These findings are considered a verification of the proposed concept. Furthermore, the rotor water cooling approach improved the stability of the system operation and although its physical behavior was not fully resolved, the study was able to verify its feasibility. In addition, at below 200 € /kW, the turbogenerator costs are competitive against competing technologies.
Lähdeviite
Grönman, A., Nerg, J., Sikanen, E., Sillanpää, T., Nevaranta, N., Scherman, E., Uusitalo, A. Uzhegov, N. Smirnov, A., Honkatukia, J., Sallinen, Jastrzebski, R. P., Heikkinen, J., Backman, J., Pyrhönen, J., Pyrhönen, O., Sopanen, J. and Turunen-Saaresti, T. (2020). Design and verification of a hermetic high-speed turbogenerator concept for biomass and waste heat recovery applications. Energy Conversion and Management, Vol. 225, December 1, pp. 113427. DOI: 10.1016/j.enconman.2020.113427
Alkuperäinen verkko-osoite
https://www.sciencedirect.com/science/article/pii/S0196890420309614?via%3DihubKokoelmat
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