Zi Ming Kou scite author profile

et al. 2012

AMR

In order to study dynamic characteristics of fluid filled pipe under hydraulic excitation force generated actively by a new developed vibration exciter, at first mathematical model of pulsating fluid was established and a computer code based on the method of characteristics (MOC) was developed. Then the excitation force calculated by MOC was forced upon the corresponding nodes of finite element of pipe, meanwhile, the nodes of fluid by MOC were assured to coincide with that of the pipe by the method of finite element (FEM). Finally, using Newmark’s method, the dynamic response at every cross section of pipe was solved. The numerical simulations show that a simple harmonic motion arises at every cross section of the pipe. The lateral vibration amplitude of every node along the pipe increases as the rising system pressure. So, this work is expected to provide some theoretical and exploratory basis for studying two dimensional vibration characteristics of fluid filled pipe.

A New Hydraulic Excitation Mode with Liquid-Filled Pipe

et al. 2011

AMR

The current vibration modes, whether inertial vibration or hydraulic vibration, have some problems such as large power consumption and low energy utilization rate. A new low energy hydraulic excitation mode is presented. This mode takes the high-pressured pipe as the new excitation source. Periodic pressure pulsation generated by wave exciter makes the pipe vibrating. The vibration mode of pipe with fluid-structure interaction is established and solved with numerical method. The modal analysis and the simulation of the vibration have been carried out. An experimental platform is built to verify that the new hydraulic vibration can be exploited.

Numerical Simulation and Experimental Analysis of an Active Hydraulic Excitation System Based on Pulsating Flow

Zhang

et al. 2011

AMR

A vibration wave generated actively by hydraulic vibration exciter was studied, and an experimental system based on the theory of water hammer was designed. The new developed vibration exciter is driven by the motor whose rotary speed can be adjusted by frequency converter, by means of which transient pulsating flow is generated regularly. Consequently the piston of hydraulic cylinder is driven periodically with the rotation of vibration exciter. Furthermore, mathematical model was established by the method of characteristics and computer code was developed to calculate numerical solution. The simulation results show that there are different flow velocities distributed at every cross section along the pipe. Measured data is basically consistent with the numerical simulation, which indicates that the vibration parameters of hydraulic cylinder can be controlled effectively.

Numerical Simulation and Analysis of Hydraulic Excitation System Based on Water Hammer by the Method of Characteristics

Zhang

et al. 2011

AMR

To study artificially produced and actively controlled water hammer wave caused by hydraulic vibration exciter, a mathematical model was established and an experimental system was designed to verify it. Through the given partial differential equations, a computer code based on the method of characteristics was developed to calculate transient pressure distributed along the pipe under different rotational frequency of vibration exciter. The numerical simulation indicates that there is a simple harmonic vibration rising at the cross sections along the pipe, corresponding to different excitation pressure at every cross section. In addition, the excitation pressure can also be adjusted by system pressure via overflow valve. So, this work is expected to serve for the optimum design of the hydraulic excitation system and play a theoretical guiding role to experimental research in future.

Based on Risk Source Tanks Leakage Adaptive Strong Magnetic Emergency Device and Sealing Method Research

Yan

Gao

et al. 2011

AMM

Along with the rapid development of chemical industry and the progress of science and technology, a large number of risk source tanks safe hidden trouble, this paper there with the present risk source leaking take on the basis of conventional containment measures, design a kind of adaptive strong magnetic emergency device, and introduces its rapid sealing method, it includes the rapid adjustable bits institutions, strong magnetic containment institutions and pressure, it is in switch diversion institutions with eternal magnets, universal of dynamic compaction ring and soft rubber balloon as sealing the ductility of the original, using rubber sealing, universal and with dynamic pressure locking ring with the move in all directions, adapted to the storage tank of planar, curved surface, large pipe outside surface and so on the different radius of curvature of the leak sealing kiss magnets, and simple structure, convenient operation, satisfy the production equipments of chemical industry and gas liquid storage facilities outside surface leakage occurs rapidly blocked.