Modeling and Analysis of Suspension Frame of Maglev Train

With the upsurge of magnetic levitation construction and research in China, in order to improve the running speed of mid-low-speed maglev train, the 13th Five-Year Science and Technology Major Proposal put forward a medium speed maglev solution with long stator synchronous traction. According to this new plan, the magnetic levitation subsystem, including the control system, needs re-co-ordination design, and the car network system must be changed accordingly. In this paper, based on the original scheme, a new magnetic levitation vehicle network system is designed to meet the needs of localization. In this paper, colored Petri nets are used to model and analyze the original scheme and the improved scheme. It proves theoretically that the improvement scheme is superior to the original scheme in failure rate and can meet the actual project requirements.

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Dynamic analysis of the interactions between a low-to-medium-speed maglev train and a bridge: Field test results of two typical bridges

Proceedings of the Institution of Mechanical Engineers Part F Journal of Rail and Rapid Transit ◽

10.1177/0954409718758502 ◽

2018 ◽

Vol 232 (7) ◽

pp. 2039-2059 ◽

Cited By ~ 11

Author(s):

Xiaozhen Li ◽

Dangxiong Wang ◽

Dejun Liu ◽

Lifeng Xin ◽

Xun Zhang

Keyword(s):

Dynamic Characteristics ◽

High Speed ◽

Field Experiments ◽

Maglev Train ◽

Coupled Vibrations ◽

Electromagnetic Suspension ◽

Car Body ◽

Medium Speed ◽

Low Speeds ◽

Suspension Frame

The rated suspension gap of a low-to-medium-speed maglev train with electromagnetic suspension is normally 8–10 mm. However, while either passing over a bridge or being stationary on one, the maglev train deforms the bridge and therefore alters the suspension gap. Hence, a problem arises due to coupled vibrations between the maglev train and its supporting bridge. In the study reported here, field experiments were conducted on the Chinese Changsha maglev line, which was the first commercial low-to-medium-speed maglev line in China. The focus is on two types of pre-stressed double-track concrete bridges on the maglev line. One is a simply supported girder with a span of 25 m, while the other is a continuous girder designed as 25 + 35 + 25 m. The accelerations and vertical dynamic deflections of the two bridges at midspan were measured while a five-module low-to-medium-speed maglev train with electromagnetic suspension either passed over or was stationary on either bridge, as were the accelerations of the car body and the suspension frame. The basic dynamic characteristics of the two bridges are analysed and compared with those of bridges in various typical maglev lines. The vibration characteristics of the two bridges, the car body and the suspension frame are studied in the time and frequency domains for the maglev train running at normal speeds, low speeds and when stationary. The influences of the speed on the dynamic characteristics are discussed. Some comparisons with other studies are also carried out, including the effects of bridge parameters on the coupled vibrations and the running stability of a low-to-medium-speed maglev and a CRH2C wheel/rail train. Significant conclusions are drawn from the analysis: increasing the rigidity and mass of the bridge can significantly reduce its vibration; increasing the span and deflection of the bridge increases the vibrations of the car body and the suspension frame; the dynamics of the maglev vehicle and bridges are different when the maglev train runs at normal speeds (more than 30 km/h), low speeds (less than 30 km/h) and when being stationary. The running stability of a low-to-medium-speed maglev train is better than that of a CRH2C high-speed train. The present study provides a test basis for further research on the mechanisms for coupled vibrations of maglev train–bridge systems.

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Kinematics Modeling and Analysis of Mid-Low Speed Maglev Vehicle with Screw and Product of Exponential Theory

Symmetry ◽

10.3390/sym11101201 ◽

2019 ◽

Vol 11 (10) ◽

pp. 1201

Author(s):

Peng Leng ◽

Jie Li ◽

Yuxin Jin

Keyword(s):

Screw Theory ◽

Theoretical Framework ◽

Parallel Structure ◽

Transition Curve ◽

Maglev Train ◽

Design Work ◽

Modeling And Analysis ◽

Kinematics Modeling ◽

Curve Modeling ◽

New Type

Maglev transportation is a new type of rail transit, whose vehicle is different from the two-bogie structure of the wheel-rail train. Generally, it consists of four to five suspension frames supporting a car body in parallel. The moving mechanism of a vehicle often consists of hundreds of moving parts, showing a multi-rigid body system in serial-parallel structure. At present, there is no theoretical framework for systematically and accurately describing the kinematics and dynamics of the Maglev train. The design work is at the level of simple equivalent estimation or measurement from the CAD drawing, which makes the system performance analysis and optimization work unable to be carried out scientifically. Based on the theoretical framework of screw theory and exponential mapping, the forward kinematics modeling, inverse kinematics solution, transition curve modeling and computational analysis methods for the Maglev train are proposed in this paper. A systematic and accurate theoretical framework is constructed for the modeling and analysis of the motion mechanism of the Maglev train, which makes the design and analysis of the Maglev train at the scientific level.

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Modeling and analysis of an intersection on AGT

Electrical Engineering in Japan ◽

10.1002/ecja.4400641004 ◽

1981 ◽

Vol 64 (10) ◽

pp. 18-27

Author(s):

Yoshio Hamamatsu ◽

Katsuhiro Nakada ◽

Ikuo Kaji ◽

Osamu Doi

Keyword(s):

Modeling And Analysis

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Judgments under uncertainty and time pressure: Modeling and analysis of operators' judgments of customers' creditworthiness

PsycEXTRA Dataset ◽

10.1037/e577392012-045 ◽

2005 ◽

Author(s):

Younho Seong

Keyword(s):

Time Pressure ◽

Modeling And Analysis

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Modeling and analysis of aging behavior of concrete structures in nuclear power plants

Revue Générale Nucléaire ◽

10.1051/rgn/20111115 ◽

2011 ◽

pp. 115-126

Author(s):

Joseph Y. R. Rashid ◽

Randy J. James ◽

Robert S. Dunham,

Keyword(s):

Nuclear Power ◽

Power Plants ◽

Nuclear Power Plants ◽

Concrete Structures ◽

Aging Behavior ◽

Modeling And Analysis

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Simulation and Analysis of Two-Mass Suspension Modification Using MATLAB Programming

ACMIT Proceedings ◽

10.33555/acmit.v3i1.39 ◽

2019 ◽

Vol 3 (1) ◽

pp. 160-165

Author(s):

Hendry D. Chahyadi

Keyword(s):

Vibrational Energy ◽

State Space Model ◽

Mass System ◽

Modeling And Analysis ◽

The Road ◽

Final Project ◽

Quarter Car ◽

Automotive Suspension ◽

Mass Spring ◽

Matlab Programming

The designs of automotive suspension system are aiming to avoid vibration generated by road condition interference to the driver. This final project is about a quarter car modeling with simulation modeling and analysis of Two-Mass modeling. Both existing and new modeling are being compared with additional spring in the sprung mass system. MATLAB program is developed to analyze using a state space model. The program developed here can be used for analyzing models of cars and vehicles with 2DOF. The quarter car modelling is basically a mass spring damping system with the car serving as the mass, the suspension coil as the spring, and the shock absorber as the damper. The existing modeling is well-known model for simulating vehicle suspension performance. The spring performs the role of supporting the static weight of the vehicle while the damper helps in dissipating the vibrational energy and limiting the input from the road that is transmitted to the vehicle. The performance of modified modelling by adding extra spring in the sprung mass system provides more comfort to the driver. Later on this project there will be comparison graphic which the output is resulting on the higher level of damping system efficiency that leads to the riding quality.

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