Automated complex for vibration stability testing of devices

被引:0
|
作者
B. B. Baidyusenov
S. I. Gerasimov
机构
[1] All-Russia Research Institute of Experimental Physics,Russian Federal Nuclear Center
[2] National Research Nuclear University MEPHI,Sarov Institute of Physics and Technology
[3] Alekseev State Technical University,undefined
[4] Nizhni Novgorod,undefined
来源
Instruments and Experimental Techniques | 2015年 / 58卷
关键词
Linear Acceleration; Testing Complex; Test Schedule; Rotational Machine; Antiresonance Frequency;
D O I
暂无
中图分类号
学科分类号
摘要
An automated testing complex composed of a vibrorotational assembly and a control system is described. The vibrorotational assembly provides complex mechanical loading on the tested device and monitoring of its response to this effect, and the control system ensures the testing safety. Using this assembly, it is possible to simultaneously generate a linear acceleration as high as 20g and vibrations in the orthogonal plane with an amplitude of up to 20g and a frequency as high as 100 Hz. Experimental results illustrating the capabilities of the testing complex are presented.
引用
收藏
页码:569 / 573
页数:4
相关论文
共 50 条
  • [31] Linear electromagnetic devices for vibration damping and energy harvesting: Modeling and testing
    Zhu, Songye
    Shen, Wen-ai
    Xu, You-lin
    ENGINEERING STRUCTURES, 2012, 34 : 198 - 212
  • [32] Smartphone-Based Automated Non-Destructive Testing Devices
    Petryk, V. F.
    Protasov, A. G.
    Galagan, R. M.
    Muraviov, A., V
    Lysenko, I. I.
    DEVICES AND METHODS OF MEASUREMENTS, 2020, 11 (04): : 272 - 278
  • [33] An automated SAR measurement system for compliance testing of personal wireless devices
    Yu, QS
    Gandhi, OP
    Aronsson, M
    Wu, D
    IEEE TRANSACTIONS ON ELECTROMAGNETIC COMPATIBILITY, 1999, 41 (03) : 234 - 245
  • [34] Automated SAR measurement system for compliance testing of personal wireless devices
    Univ of Utah, Salt Lake City, United States
    IEEE Trans Electromagn Compat, 3 (234-245):
  • [35] FuRong: Fusing Report of Automated Android Testing on Multi-Devices
    Tian, Yuanhan
    Yu, Shengcheng
    Fang, Chunrong
    Li, Peiyuan
    2020 ACM/IEEE 42ND INTERNATIONAL CONFERENCE ON SOFTWARE ENGINEERING: COMPANION PROCEEDINGS (ICSE-COMPANION 2020), 2020, : 49 - 52
  • [36] ON THE DYNAMIC ANALYSIS OF THE COMPLEX STRUCTURES BY VIBRATION TESTING OF THE SUBSTRUCTURES.
    Silas, G.H.
    Revue roumaine des sciences techniques. Serie de mecanique appliquee, 1985, 30 (05): : 467 - 476
  • [37] OUTDOOR PERFORMANCE AND STABILITY TESTING OF THIN-FILM DEVICES
    DEBLASIO, R
    WADDINGTON, D
    MRIG, L
    SOLAR CELLS, 1987, 21 : 343 - 351
  • [38] 3-DIMENSIONAL STABILITY TESTING OF SPINAL FIXATION DEVICES
    PANJABI, MM
    ORTHOPADE, 1991, 20 (02): : 106 - 111
  • [39] Consensus stability testing protocols for organic photovoltaic materials and devices
    Reese, Matthew O.
    Gevorgyan, Suren A.
    Jorgensen, Mikkel
    Bundgaard, Eva
    Kurtz, Sarah R.
    Ginley, David S.
    Olson, Dana C.
    Lloyd, Matthew T.
    Moryillo, Pasquale
    Katz, Eugene A.
    Elschner, Andreas
    Haillant, Olivier
    Currier, Travis R.
    Shrotriya, Vishal
    Hermenau, Martin
    Riede, Moritz
    Kirov, Kiril R.
    Trimmel, Gregor
    Rath, Thomas
    Inganas, Olle
    Zhang, Fengling
    Andersson, Mattias
    Tvingstedt, Kristofer
    Lira-Cantu, Monica
    Laird, Darin
    McGuiness, Christine
    Gowrisanker, Srinivas
    Pannone, Michael
    Xiao, Min
    Hauch, Jens
    Steim, Roland
    DeLongchamp, Dean M.
    Roesch, Roland
    Hoppe, Harald
    Espinosa, Nieves
    Urbina, Antonio
    Yaman-Uzunoglu, Gulsah
    Bonekamp, Joerg-Bernd
    van Breemen, Albert J. J. M.
    Girotto, Claudio
    Voroshazi, Eszter
    Krebs, Frederik C.
    SOLAR ENERGY MATERIALS AND SOLAR CELLS, 2011, 95 (05) : 1253 - 1267
  • [40] Automated scoring of complex tasks in computer-based testing
    Hendrickson, Amy
    JOURNAL OF EDUCATIONAL MEASUREMENT, 2007, 44 (04) : 385 - 390
12345