External Neutron Source for Research Reactor Based on Linear Accelerator and Beryllium Target

Standard

External Neutron Source for Research Reactor Based on Linear Accelerator and Beryllium Target. / Struev, V.P.; Bogdanov, A.A.; Golovkina, A.G.; Kiselev, Yu.V.; Kudinovich, I.V.; Laikin, A.I.; Rubanov, S.M.

Proceedings of 5th Int. Particle Accelerator Conference (IPAC), Dresden, Germany. 2014. p. 754-756.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Research

Harvard

Struev, VP, Bogdanov, AA, Golovkina, AG, Kiselev, YV, Kudinovich, IV, Laikin, AI & Rubanov, SM 2014, External Neutron Source for Research Reactor Based on Linear Accelerator and Beryllium Target. in Proceedings of 5th Int. Particle Accelerator Conference (IPAC), Dresden, Germany. pp. 754-756. <http://accelconf.web.cern.ch/AccelConf/IPAC2014/papers/mopri066.pdf>

APA

Struev, V. P., Bogdanov, A. A., Golovkina, A. G., Kiselev, Y. V., Kudinovich, I. V., Laikin, A. I., & Rubanov, S. M. (2014). External Neutron Source for Research Reactor Based on Linear Accelerator and Beryllium Target. In Proceedings of 5th Int. Particle Accelerator Conference (IPAC), Dresden, Germany (pp. 754-756) http://accelconf.web.cern.ch/AccelConf/IPAC2014/papers/mopri066.pdf

Vancouver

Struev VP, Bogdanov AA, Golovkina AG, Kiselev YV, Kudinovich IV, Laikin AI et al. External Neutron Source for Research Reactor Based on Linear Accelerator and Beryllium Target. In Proceedings of 5th Int. Particle Accelerator Conference (IPAC), Dresden, Germany. 2014. p. 754-756

Author

Struev, V.P. ; Bogdanov, A.A. ; Golovkina, A.G. ; Kiselev, Yu.V. ; Kudinovich, I.V. ; Laikin, A.I. ; Rubanov, S.M. / External Neutron Source for Research Reactor Based on Linear Accelerator and Beryllium Target. Proceedings of 5th Int. Particle Accelerator Conference (IPAC), Dresden, Germany. 2014. pp. 754-756

BibTeX

@inproceedings{8bb46ad55bf044599ba77907287e1cc0,

title = "External Neutron Source for Research Reactor Based on Linear Accelerator and Beryllium Target",

abstract = "Nuclear power plant based on accelerator driven subcritical reactor (ADSR) is considered. Such systems demonstrate higher safety because the fission proceeds in subcritical core and necessary neutron flux is reached with external neutrons generated in target of heavy nuclides. In order to efficiently use ADSR for energy production, it{\textquoteright}s needed the total power, generated in the reactor, to be greater than power inputs for charged particles acceleration. The plant driven by middle-energy accelerator, which is cheaper than high-energy accelerators, proposed for these purposes, is considered. So it{\textquoteright}s necessary to find other ways to amplify reactor power outputs. Thus, the technical solution to increase power gain of small-sized power plant with a linear proton accelerator (energy 300-400 MeV, average current 5 mA) is proposed. Thermal power up to 300 MW was reached.",

author = "V.P. Struev and A.A. Bogdanov and A.G. Golovkina and Yu.V. Kiselev and I.V. Kudinovich and A.I. Laikin and S.M. Rubanov",

year = "2014",

language = "English",

isbn = "9783954501328",

pages = "754--756",

booktitle = "Proceedings of 5th Int. Particle Accelerator Conference (IPAC), Dresden, Germany",

}

RIS

TY - GEN

T1 - External Neutron Source for Research Reactor Based on Linear Accelerator and Beryllium Target

AU - Struev, V.P.

AU - Bogdanov, A.A.

AU - Golovkina, A.G.

AU - Kiselev, Yu.V.

AU - Kudinovich, I.V.

AU - Laikin, A.I.

AU - Rubanov, S.M.

PY - 2014

Y1 - 2014

N2 - Nuclear power plant based on accelerator driven subcritical reactor (ADSR) is considered. Such systems demonstrate higher safety because the fission proceeds in subcritical core and necessary neutron flux is reached with external neutrons generated in target of heavy nuclides. In order to efficiently use ADSR for energy production, it’s needed the total power, generated in the reactor, to be greater than power inputs for charged particles acceleration. The plant driven by middle-energy accelerator, which is cheaper than high-energy accelerators, proposed for these purposes, is considered. So it’s necessary to find other ways to amplify reactor power outputs. Thus, the technical solution to increase power gain of small-sized power plant with a linear proton accelerator (energy 300-400 MeV, average current 5 mA) is proposed. Thermal power up to 300 MW was reached.

AB - Nuclear power plant based on accelerator driven subcritical reactor (ADSR) is considered. Such systems demonstrate higher safety because the fission proceeds in subcritical core and necessary neutron flux is reached with external neutrons generated in target of heavy nuclides. In order to efficiently use ADSR for energy production, it’s needed the total power, generated in the reactor, to be greater than power inputs for charged particles acceleration. The plant driven by middle-energy accelerator, which is cheaper than high-energy accelerators, proposed for these purposes, is considered. So it’s necessary to find other ways to amplify reactor power outputs. Thus, the technical solution to increase power gain of small-sized power plant with a linear proton accelerator (energy 300-400 MeV, average current 5 mA) is proposed. Thermal power up to 300 MW was reached.

M3 - Conference contribution

SN - 9783954501328

SP - 754

EP - 756

BT - Proceedings of 5th Int. Particle Accelerator Conference (IPAC), Dresden, Germany

ER -

ID: 7005760