Stability Control of a Self-Propelled Crane in Dynamic Loading

被引:2
|
作者
Vatulin Y.S. [1 ]
Potakhov D.A. [1 ]
机构
[1] Saint Petersburg State Transport University, St. Petersburg
来源
Vatulin, Ya. S. (yan-roos@yandex.ru); Potakhov, D.A. (Schan-di@mail.ru) | 1600年 / Pleiades Publishing卷 / 40期
关键词
control systems; dynamic loads; numerical simulation; self-propelled crane; stability;
D O I
10.3103/S1068798X20070254
中图分类号
学科分类号
摘要
Abstract: A stability control system is developed for a self-propelled crane in dynamic loading. The simulation of crane operation takes account of the flexural deformation of the elements and the operation of the hydraulic drive, along with interactive control. The simulation is based on the integration of Matlab Simulink, Fuzzy Logic Toolbox, and SolidWorks CAD 3D modeling software. © 2020, Allerton Press, Inc.
引用
收藏
页码:545 / 550
页数:5
相关论文
共 50 条
  • [31] Numerical simulation of a self-propelled fish-like swimmer with rigid and flexible caudal fins
    Feng, Y. K.
    Su, Y. M.
    Liu, H. X.
    Su, Y. Y.
    JOURNAL OF ENVIRONMENTAL BIOLOGY, 2020, 41 (02) : 161 - 170
  • [32] Study on numerical simulation method and mechanism of bionic robot fish's self-propelled swimming
    Feng Y.
    Su Y.
    Su Y.
    Liu H.
    Huazhong Keji Daxue Xuebao (Ziran Kexue Ban)/Journal of Huazhong University of Science and Technology (Natural Science Edition), 2019, 47 (12): : 18 - 24
  • [33] STUDY OF SELF-PROPELLED PUFFERFISH DRIVEN BY MULTIPLE FINS - A COMPARISION BETWEEN RIGID AND DEFORMABLE FINS
    Li, Ruoxin
    Xiao, Qing
    Li, Lijun
    Liu, Hao
    PROCEEDINGS OF THE ASME 36TH INTERNATIONAL CONFERENCE ON OCEAN, OFFSHORE AND ARCTIC ENGINEERING, 2017, VOL 7A, 2017,
  • [34] Radioactive Uranium Preconcentration via Self-Propelled Autonomous Microrobots Based on Metal-Organic Frameworks
    Ying, Yulong
    Pourrahimi, Amir Masoud
    Sofer, Zdenek
    Matejkova, Stanislava
    Pumera, Martin
    ACS NANO, 2019, 13 (10) : 11477 - 11487
  • [35] Unsteady three-dimensional boundary element method for self-propelled bio-inspired locomotion
    Moored, K. W.
    COMPUTERS & FLUIDS, 2018, 167 : 324 - 340
  • [36] On Collision Avoiding Fixed-Time Flocking with Measurable Diameter to a Cucker-Smale-Type Self-Propelled Particle Model
    Xiao, Qizhen
    Liu, Hongliang
    Xu, Zhenghua
    Ouyang, Zigen
    COMPLEXITY, 2020, 2020 (2020)
  • [37] Optimal control of a container crane by a fuzzy logic controller, robustness and stability
    Masmoudi, NK
    Djemel, M
    Rekik, C
    MESM 2005: 7TH MIDDLE EAST SIMULATION MULTICONFERENCE, 2005, : 70 - 75
  • [38] Numerical simulation on the flow field of self-propelled multi-orifices nozzle for ultra-short radius radial jet drilling
    Zhang, X.
    Liu, X.
    Geng, D.
    Yu, W.
    Shi, L.
    INTERNATIONAL JOURNAL OF OIL GAS AND COAL TECHNOLOGY, 2018, 17 (01) : 1 - 11
  • [39] A DES-based study of the flow around the self-propelled DARPA Suboff working in deep immersion and beneath the free-surface
    Lungu, Adrian
    OCEAN ENGINEERING, 2022, 244
  • [40] METHOD FOR STABILITY ANALYSIS OF A WOODEN COUPLING BAR UNDER DYNAMIC LOADING
    Savin, S. Yu.
    V. Fedorova, N.
    RUSSIAN JOURNAL OF BUILDING CONSTRUCTION AND ARCHITECTURE, 2022, (03): : 19 - 29
12345