B16 Dynamic Analysis of Jump Motion Based on Multi-body Dynamics : Contribution of Joint Torques to Angular Momentum of Body

Based on Dynamics of Flexible Multi-body theories, the flexible multi-body model of tower crane is established, by using the module of ADAMS/FLEX. The vibration characteristics of tower crane is analysed during the case of braking slewing motion by introducing the modal neutral file of tower crane flexible jib and mast. Advices are given in this paper for the dynamic analysis and the control design of tower crane.

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Fully-coupled Multi-Body Dynamics and Nonlinear Structural Analysis Applied to Automotive Dynamic Analysis

10.4271/2010-01-0948 ◽

2010 ◽

Cited By ~ 1

Author(s):

Steven Rennich

Keyword(s):

Structural Analysis ◽

Dynamic Analysis ◽

Nonlinear Structural Analysis ◽

Nonlinear Structural ◽

Body Dynamics ◽

Multi Body ◽

Fully Coupled

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A Comprehensive Inverse Dynamics Problem of a Stewart Platform by Means of Lagrangian Formulation

Volume 1: Aerospace Applications; Advances in Control Design Methods; Bio Engineering Applications; Advances in Non-Linear Control; Adaptive and Intelligent Systems Control; Advances in Wind Energy Systems; Advances in Robotics; Assistive and Rehabilitation Robotics; Biomedical and Neural Systems Modeling, Diagnostics, and Control; Bio-Mechatronics and Physical Human Robot; Advanced Driver Assistance Systems and Autonomous Vehicles; Automotive Systems ◽

10.1115/dscc2017-5098 ◽

2017 ◽

Cited By ~ 2

Author(s):

Naser Mostashiri ◽

Alireza Akbarzadeh ◽

Jaspreet Dhupia ◽

Alexander Verl ◽

Weiliang Xu

Keyword(s):

Inverse Dynamics ◽

Virtual Work ◽

Stewart Platform ◽

Joint Torques ◽

Body Dynamics ◽

Inverse Kinematics Problem ◽

Simplifying Assumptions ◽

Inverse Dynamics Problem ◽

Multi Body ◽

Lagrange’S Method

In this paper, using the Lagrange’s method a comprehensive inverse dynamics problem of a 6-3 UPS Stewart platform is investigated. First, the inverse kinematics problem is solved and the Jacobian matrix is derived. Next, the full inverse dynamics problem of the robot, taking into account the mass of links and inertia, is investigated and its governing equations are derived. The correctness of the dynamics equations are verified in two ways, first, using the results of the virtual work method and second using the results of a commercial multi-body dynamics software. Because the dynamic calculation is time consuming, two simplifying assumptions are considered. First, the link is assumed to have a zero mass and next it is assumed as a point mass. Studying the former assumption is rather straightforward. However, more complex equations are needed and derived in the present paper for the latter assumption. Required actuator forces for the two assumptions are compared with the case where the mass and link inertial is fully considered. It is shown that the first simplifying assumption significantly affects the accuracy of the required joint torques.

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Multi-body dynamics co-simulation of hoisting wire rope

The Journal of Strain Analysis for Engineering Design ◽

10.1177/0309324717744146 ◽

2017 ◽

Vol 53 (1) ◽

pp. 36-45 ◽

Cited By ~ 3

Author(s):

Qing Huang ◽

Zhi Li ◽

Hong-qian Xue

Keyword(s):

Finite Element ◽

Finite Element Model ◽

Dynamic Analysis ◽

Dynamic Model ◽

Loading Condition ◽

Element Model ◽

Wire Rope ◽

Body Dynamics ◽

Hoisting System ◽

Multi Body

As more wire ropes with complex construction are used in the hoisting system of a crane, it becomes more necessary to predict the risks of the hoisting operation. Especially the wire rope, dynamic analysis is required to manage the potential risk in advance. Thus, in this article, a co-simulation method based on multi-body dynamics and finite element method is proposed to determine the dynamic responses of a hoisting system and wire rope. We developed a dynamic model of hoisting system based on ADAMS/Cable to formulate the time history response of dynamic force on wire rope, which could be used as the loading condition in the posterior finite element model. A three-dimensional geometric model for the multi-layered strands wire rope with a construction of 1+7+7 / 7+14 wires is implemented in the finite element analysis software ABAQUS, and both static and dynamic analyses are presented. The static analysis result of force–strain relation is compared with several experiment data, and the finite element model is proved accurate and reliable. In the latter case, the force–time curves obtained by dynamic model are imported to finite element model as loading condition to accomplish dynamic analysis. The co-simulation results of hoisting wire rope’s behavior subjected to dynamic loading during the hoisting process are carried out and discussed. The stress distribution and stress spectrum of wire rope are obtained, and the results show that the most dangerous regions are the lateral side of wire rope, especially the contact area of two wires in strands.

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Dynamic analysis of a floating wind turbine in wet tows based on multi-body dynamics

Journal of Renewable and Sustainable Energy ◽

10.1063/1.4982742 ◽

2017 ◽

Vol 9 (3) ◽

pp. 033301 ◽

Cited By ~ 3

Author(s):

Hongyan Ding ◽

Yanqing Han ◽

Conghuan Le ◽

Puyang Zhang

Keyword(s):

Dynamic Analysis ◽

Wind Turbine ◽

Floating Wind Turbine ◽

Body Dynamics ◽

Multi Body

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Dynamic Analysis on Crank-Slider Mechanism of Reciprocating Pump

Materials Science Forum ◽

10.4028/www.scientific.net/msf.697-698.676 ◽

2011 ◽

Vol 697-698 ◽

pp. 676-680

Author(s):

Z.G. Han ◽

Qing Jian Liu

Keyword(s):

Dynamic Response ◽

Dynamic Analysis ◽

Dynamic Model ◽

Dynamic Behavior ◽

Rotational Speed ◽

Analysis And Design ◽

Numerical Example ◽

Body Dynamics ◽

Reciprocating Pump ◽

Multi Body

The crank-slider mechanism is the key component in reciprocating pumps. With the increase of the rotational speed of the crank-slider mechanism, the vibration and working noise of reciprocating pumps increase. Based on the multi-body dynamics theory, the dynamic model of the crank-slider mechanism of reciprocating pumps is proposed. A numerical example is given and the validity of the procedure developed here is demonstrated by analyzing the dynamic behavior of a typical crank-slider mechanism of the reciprocating pump. The model can well simulate the dynamic response of the mechanism, which can enable designers to obtain required information on the analysis and design of reciprocating pumps.

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