Your search keyword '"Finite element software"' showing total 1,993 results

1. Dynamic Model Reduction for Viscously Damped Structures with Statically Determinate Interfaces.

Author

Lian-Kai Xu, Wei Wang, Wang-Bai Pan, and Guo-An Tang

Abstract

A novel model reduction method for viscously damped structures with statically determinate interfaces, such as spacecraft flexible appendages, is proposed. The paper presents a derivation of the complete complex modal expansion of the interface dynamic stiffness of these structures. Based on the identity relation for all complex modes, which is obtained during the derivation, it is found that the interface acceleration impedance can be expressed as a rational fraction with high accuracy using only low-order complex modes. Using this rational fraction as an approximation model, numerical results of the frequency response can be fitted. The fitted interface acceleration impedance can be applied to real-time control as a reduced model in the form of a transfer function. Furthermore, it can be transformed into the form of system matrices by introducing auxiliary variables, which then participate in the dynamic analysis of the assembly. The reduction process circumvents complex modal analysis and necessitates only the results of frequency responses. Thanks to the powerful ability of conventional finite element software to perform frequency response analysis, this reduction method can be used for large-scale complex models in actual engineering applications. [ABSTRACT FROM AUTHOR]

Published

2024

2. New Analytical Solutions for Free Vibration of Cracked Functionally Graded Rectangular Plates.

Author

Zhaoyang Hu, Yueqing Shi, Chengjie Guo, Jingyu Du, and Rui Li

Abstract

In aerospace engineering, the existence of cracks highly alters the mechanical behaviors of structural components. As a new class of key structural components, functionally graded material (FGM) rectangular plates with an interior/side crack are focused on in this study. New analytical free vibration solutions are put forward for such cracked FGM plates. First, a cracked plate is decomposed into several subplates with the necessary continuity conditions to address the physical discontinuity issue caused by the crack. The challenge then becomes deriving analytical free vibration solutions for each subplate. To accomplish this task, a symplectic superposition method (SSM) is developed to deal with FGM rectangular plates with various boundary conditions, including the complex continuity conditions. The SSM eliminates the need for a predefined solution form, and its solution procedure, including variable separation and eigen expansion, is mathematically rigorous. Afterward, the analytical solutions obtained via the SSM are integrated to serve as the final free vibration solution of the cracked FGM plate. Comprehensive results based on the obtained analytical solutions, including natural frequencies and vibration modes, are presented and validated. The solutions are further used to investigate the effects of some important parameters, such as crack length and crack location. [ABSTRACT FROM AUTHOR]

Published

2024

3. Identification of Structural Damage Location and Severity Using Deep Learning

Author

Adhikari, Sandip Kumar Roy, Srinivasan, Sivakumar M., Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Tolio, Tullio A. M., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Schmitt, Robert, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Chandrashekara, C. V., editor, Mathivanan, N. Rajesh, editor, and Hariharan, K., editor

Published

2024

4. Application of Mass Particle Methods in the Shape Design for Scientific Balloons.

Author

Hangyue Zhang, Yanchu Yang, and Rong Cai

Abstract

This paper proposes a dynamic simulation method for solving balloon shapes. The mass-spring-damping model is used to discretize two-dimensional generatrixes and three-dimensional membrane surfaces, respectively. We solve two-dimensional/three-dimensional ascent shapes at different zero-pressure heights and numerically simulate mushroom cloud shapes that occur during the balloon ground launch. The typical rapid transition feature of the mushroom cloud shape at the waist is depicted. In addition, a preliminary numerical simulation study was conducted for the pumpkin superpressure balloon deployment instability problem. The Calladine instability critical curve for constant angle design lobes is compared and validated for different gore numbers and lobe angles. Further, simulations were carried out on fully inflated shapes of two derived superpressure balloon designs developed by the Japan Aerospace Exploration Agency/Institute of Space and Astronautical Science, namely, the Tawara intermediate cylindrical segment balloon and the diamond-shaped tendon balloon. We verify the ISAS conclusion that the diamond-shaped tendon balloon has a cylindrical shape when fully inflated. Finally, a preliminary simulation study was carried out on the deployment shape of four ballonet architectures in the superpressure balloon. The proposed method for solving various types of balloon shapes based on the mass particle method is simple and efficient, and it has been well applied in our actual balloon engineering. [ABSTRACT FROM AUTHOR]

Published

2024

5. Numerical Evaluation of Liquefaction During Vibratory Pile Driving in Saturated Sand

Author

Fadaei, Sepideh and Hamidi, Amir

Published

2024

6. Numerical Modelling of Historical Masonry Structures with the Finite Element Code NOSA-ITACA

Author

Girardi, Maria, Padovani, Cristina, Pellegrini, Daniele, Porcelli, Margherita, Robol, Leonardo, Patrizio, Giorgio, Editor-in-Chief, Alberti, Giovanni, Series Editor, Bracci, Filippo, Series Editor, Canuto, Claudio, Series Editor, Ferone, Vincenzo, Series Editor, Fontanari, Claudio, Series Editor, Moscariello, Gioconda, Series Editor, Pistoia, Angela, Series Editor, Sammartino, Marco, Series Editor, Bretti, Gabriella, editor, Cavaterra, Cecilia, editor, Solci, Margherita, editor, and Spagnuolo, Michela, editor

Published

2023

7. Finite Element Software Analysis of Engineering Structure Test and Teaching Reform of Integration of Production and Teaching

Author

Zhu, Kun, Ma, Zaiyong, Wang, Furong, Geng, Lijuan, Wu, Ruitian, Meng, Xianyue, Wang, Lin, Gao, Hui, Li, Kan, Editor-in-Chief, Li, Qingyong, Associate Editor, Fournier-Viger, Philippe, Series Editor, Hong, Wei-Chiang, Series Editor, Liang, Xun, Series Editor, Wang, Long, Series Editor, Xu, Xuesong, Series Editor, Yuan, Xueming, editor, Kurniawan, Yohannes, editor, and Ji, Zhenyan, editor

Published

2023

8. Application of Nonlinear Behaviour for Concrete Material in Numerical Simulation

Author

Linh-Nguyen, Thi Thuy, Le-Minh, Hoang, Vu-Huu, T., Cuong-Le, Thanh, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Haddar, Mohamed, Editorial Board Member, Kwon, Young W., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Rao, Ravipudi Venkata, editor, Khatir, Samir, editor, and Cuong-Le, Thanh, editor

Published

2023

9. Comparative Study of Skin-Stringer Connection Approaches for Stiffened Structures with Curvilinear Stiffeners.

Author

Wei Zhao, Junhyeon Seo, and Kapania, Rakesh K.

Abstract

Additive manufacturing enables the deposition of material in the near-net shape at any desired location on the base plate or shell to improve the structural performance by tailoring the buckling and/or vibration mode shapes. In this study, a stiffened plate with arbitrarily shaped stiffeners is modeled using a nonconformal mesh-based finite element model. Six degrees of freedom are considered for each node of the plate and the stiffener finite element models to enable the couplings between the plate's and stiffeners' in-plane and out-of-plane motions. Displacement compatibility is enforced at the interface between the plate and the stiffeners where several skin-stringer connection approaches, including inverse isoparametric mapping algorithm (IIMA), radial basis function, and thin-plate spline function, are used. Various complex models available in the literature are employed for evaluating the skin-stringer connection approaches. Research studies show that the IIMA-based nonconformal mesh modeling can generate a sparse displacement approximation matrix, which makes it an efficient approach for nonconformal mesh-based modeling. For the stiffened plate with higher stiffeners, the present results agree well with those obtained from the Abaqus/CAE conventional conformal mesh and mesh tie constraint-based nonconformal mesh modeling results, but yield better results than the Abaqus/CAE wrapping mesh approach. [ABSTRACT FROM AUTHOR]

Published

2023

10. Safety Lifetime Analysis Using Two-Phase Subset Simulation Combined with Kriging Model.

Author

Yixin Lu, Zhenzhou Lu, and Kaixuan Feng

Abstract

The safety lifetime analysis under the required time-dependent failure probability (R-FP) constraint is essential to ensure structure service safety, but existing methods are unaffordable for solving the safety lifetime under a small R-FP constraint. For this issue, a novel method is proposed by combining a two-phase subset simulation with an adaptive kriging model (TP-SS-AK). The innovations of the TP-SS-AK include three aspects. First, it creatively transforms the safety lifetime under a small R-FP constraint into that under a large conditional R-FP constraint by subset simulation, which can greatly improve efficiency because the large conditional R-FP constraint only needs a small candidate sample pool for searching the safety lifetime. Second, by deducing the misclassification probability of the time-dependent structure state in the first phase, the first new learning strategy is established to train the kriging model of the time-dependent performance function and further determine a reasonable lifetime search interval efficiently. Third, by deriving the misclassification probability of the first failure instant, the second new learning strategy is constructed to efficiently update the kriging model in the second phase and further search the safety lifetime. Because the proposed TP-SS-AK combines the advantages of the two-phase subset simulation and two new learning strategies, it is superior to the existing methods in efficiency, and its superiority is verified by the examples. [ABSTRACT FROM AUTHOR]

Published

2023

11. Experimentally Validated Progressive Failure Modeling of Composite Pi Joints.

Author

Finlay, James G., Waas, Anthony M., Davidson, Paul, Bartley-Cho, Jonathan, and Muraliraj, Nav

Abstract

A computational model has been developed to analyze composite pi joints subjected to pulloff and side-bend loading. A discrete damage modeling approach is used to capture the interactions between intralaminar damage (matrix cracking) and interlaminar damage (delamination). Cohesive element interlayers and matrix-crack elements are governed by the same mixed-mode traction-separation formulation, resulting in a unified damage framework. The finite element model was calibrated using experimental data from pristine and defective joints. In the calibration process, in situ cohesive material properties were backcalculated from pulloff tests such that the accurate prediction of structural response and the damage evolution of pi joints were possible. Computational predictions for both pulloff and side-bend loading are shown to agree well with experimental results for joints subjected to pulloff and side-bend loading. [ABSTRACT FROM AUTHOR]

Published

2023

12. Penetrator Penetrating Lunar Soil: Accurate Modeling and Parameter Analysis.

Author

Haitao Luo, Chaohui Fan, Yuxin Li, Guangming Liu, and Ziyang Liu

Abstract

This paper focuses on how to establish an accurate numerical model of penetrator penetration into the lunar soil and study the process of penetration. The lunar soil simulant was prepared according to published literature, and its plastic parameters were obtained by triaxial compression test. To determine the material model and parameters of the lunar soil simulant in numerical simulation, the corresponding numerical simulation was carried out for the triaxial test. Under the comprehensive consideration of accuracy and computational efficiency, the applicability of four numerical algorithms, including finite element method (FEM), arbitrary Lagrangian-Eulerian, smoothed particle hydrodynamics (SPH), and SPH-FEM, in the penetration simulation is evaluated. Finally, SPH-FEM is the optimal algorithm for the numerical simulation of the penetrator penetrating lunar soil. The convergence of the penetration model is tested. Finally, an accurate numerical model of the penetrator penetrating lunar soil is obtained. Then, the effects of incident velocity, incident angle, and angle of attack on penetration performance are studied, respectively, which provide reference for the design and process control of the penetrator project. [ABSTRACT FROM AUTHOR]

Published

2023

13. Using MSC.Patran as a Tool for the Numerical Stress Analysis of a Shock-loaded Bullet-resistant Door.

Author

Wei-Ling Hsu, Hong-Wei Yu, Chao-Ming Hsu, Te-Hsun Lin, and Cheng-Fu Yang

Subjects

STRAINS & stresses (Mechanics), NUMERICAL analysis, FINITE element method, STRESS concentration, EARTHQUAKE magnitude

Abstract

There are two methods commonly used to determine the effectiveness of a bullet-resistant door: one involves the use of sensors attached to various locations to detect cracking following impact and the other employs software simulations. In this study, we utilized the finite element method (FEM) analysis software MSC.Patran to perform stress analyses on a designed bullet- resistant door, subjecting it to various external forces. Utilizing the FEM simulation method eliminates the need for attached sensors to detect the effects of impacts. The focus is on developing a shock-loaded door that can withstand various impacts with minimal visible damage or deformation. In this study, we primarily examine the effects of different impacts on a designed bullet-resistant door through simulation using MSC.Patran's FEM. The software was employed to simulate and compute stress and displacement distributions, as well as the response force of the entire door structure, while assuming various conditions such as steel structure, welding strength, and material, among others, under different impact conditions. The impacts were generated by a 125 kg and 8 inch armor-piercing projectile, a car, or a solid steel ball, and an earthquake with a magnitude of roughly 6.4 was added to the stress conditions to analyze and simulate the stresses. The results of different impacted objects were discussed. The findings revealed that, under the aforementioned conditions, the designed door structure could effectively withstand external impacts without damage. On the basis of the analysis results, it was determined that the steel panel, steel structure, and latch of the bullet-resistant door were capable of resisting the combined impacts of the specified foreign objects. [ABSTRACT FROM AUTHOR]

Published

2023

14. Effect of Geogrid on Landslide Prevention of Soil Slope Under Static Loading

Author

Gupta, Shubham, Sharma, Vishal, Sarkar, Raju, Srivastava, Amit Kumar, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Adhikari, Basanta Raj, editor, and Kolathayar, Sreevalsa, editor

Published

2022

15. Numerical effect of seismic force on a medium arch dam

Author

Milad Khatib, Melissa Loutfi, Hani Hamdan, and Wahib Arairo

Subjects

finite element software, medium arch dam, pseudo-static, response spectrum, seismic loading, Environmental technology. Sanitary engineering, TD1-1066

Abstract

The dam is considered a huge structure that has multiple purposes in the life of a human. The most important role of a dam is the production of electricity, and the storage of a huge quantity of water. Therefore, it is very important to be vigilant in the studies made for it. Lebanon has indeed been designated as a seismicity country. However, the number of dams is increasing due to several natural consideration. Mseilha dam is an executed medium arch dam, which faced several problems during and after construction. The initial problem that faced a dam is the seismic force. This natural force is very dangerous for any structure, especially for a dam. It could increase the existing concrete stresses. These stresses will cause the development of cracks all along the dam. Once the concrete shows cracks, its resistance will decrease, and it will become more vulnerable to external effects. Several studies were made to fortify it and make it resistant to seismic force. To show the major effect of this force, two methods ‘pseudo-static’ and ‘response spectrum’ were applied to a medium arch dam. Therefore, to evaluate the performance of these two methods, the dam is modelled using finite element software. The obtained results show the importance of using the appropriate model in the design of such dams without taking the appropriate model. HIGHLIGHTS Highlight on one of the major problems that affect the stability of medium dam.; Clarify how to analyze this catastrophic problem and prevent the losses (Humans life and economic way).; Illustrate, through a comparison between two analysis methods, how to simulate numerically such severe problem.; Encourage the researches to take into consideration all the existed forces during analysis and design for all dam types.;

Published

2022

16. Parametric Investigation of Vibratory Responses for Reduced-Order Models of Rotating Bladed Disks.

Author

Kurstak, Eric and D'Souza, Kiran

Abstract

Attempting to predict the physical response of a complex system under realistic conditions is extremely challenging. In this work, a parametric reduced-order model (PROM) of a bladed disk is briefly presented that allows for the quick and efficient modeling of rotational speed effects and mistuning effects in bladed disks. This computational model is tuned to match experimental data. The tuned PROM is then investigated through a parametric study. Three internal parameters investigated are i) forcing magnitude, ii) mistuning value magnitude, and iii) damping magnitude, and four external parameters are iv) forcing location, v) forcing radius, vi) probe placement error, and vii) arrival time error. These parameters are common in the structural analysis of turbomachines. Each internal parameter is increased and decreased by 10, 20, and 50%, while external parameters are changed by varying amounts due to geometric and practical limitations. The model is time integrated to simulate the conditions present in the experimental test rig. The maximum blade amplitudes are then compared to the baseline case and analyzed. The damping, followed by the forcing, is shown to cause the greatest impact on the final system response. This indicates a greater need to accurately measure the damping compared to other parameters. [ABSTRACT FROM AUTHOR]

Published

2023

17. No Access Adjustment Method of Coupled Dual-Surface Accuracy for Antennas Using Interval Model Updating.

Author

Tuanjie Li, Jiangbo Wen, Zhiyang Shi, and Zijie Zeng

Abstract

Affected by the uncertainties caused by cable cutting and assembly errors, material performance dispersion, and truss deformation, the dual-surface accuracy of a mesh antenna cannot satisfy the design requirements. However, the existing methods can only adjust the accuracy of a single surface. This paper studies a method for adjusting coupled dual-surface mesh antennas considering uncertainties. Dual-reflector mesh antennas use both the front and rear reflectors for sensing, and both surfaces have shape accuracy requirements. First, an interval model updating method based on sensitivity analysis is proposed to obtain an updated interval parameters model group, which can accurately represent the relationship between adjustment cable length and surface accuracy. Then, an interval optimization function for the coupled dual-surface accuracy is established to get optimal adjustment amounts, which is solved by using the fast elitist nondominated sorting genetic algorithm (NSGA-II). Meanwhile, a kriging model is introduced to improve the optimization efficiency. Finally, the AstroMesh antenna is taken as an example to verify the validity of the proposed method. The results show that both the front and back net accuracies can be improved after adjustment, proving the proposed method's feasibility. [ABSTRACT FROM AUTHOR]

Published

2023

18. Multidisciplinary Structural Optimization of Low-Pyroshock Separation Nuts for Aerospace.

Author

Yadong Wu, Yufan Lu, Hao Yang, Yichang Liu, and Mingdong Zhou

Abstract

This paper presents a multidisciplinary structural optimization approach to design separation nuts with low-level pyroshock responses for aerospace. A parametric modeling method is developed to automatically construct a multibody finite element model for separation nuts according to the predefined structural parameters. A new explicit dynamics analysis workflow tailored to separation nuts is proposed to simulate the pyroshock environment efficiently. Based on a backpropagation neuron network technique, certain surrogate models are established to describe the equivalence relationship between the structural parameters and the multidisciplinary structural responses including the pyroshock, the bending stiffness, and the structural weight. Finally, a pyroshock minimization problem with the constraints of structural weight and bending stiffness is solved by using a genetic algorithm, resulting in an optimized low-pyroshock separation nut design. The comparison between the optimized structure and a reference structure shows the effectiveness of the proposed approach. [ABSTRACT FROM AUTHOR]

Published

2023

19. Numerical effect of veil injection on a gravity dam using grouting intensity number ‘GIN’ method

Author

Milad Khatib, Melissa Loutfi, and Hani Hamdan

Subjects

finite element software, gravity dam, ground water flow, uplift pressure force, veil injection, Environmental technology. Sanitary engineering, TD1-1066

Abstract

A dam is one of the oldest and largest buildings in the world. This structure is usually constructed to intercept flows, store water, and produce energy. Dams' foundations should really be rocky and robust enough to preserve their rigidity. Despite the great benefits of these structures, they are exposed to the risk of collapse. Two basic problems can confront a gravity dam; the first one is the uplift pressure load that could raise the danger of reversing the dam. The second one is the ground water flow, which can lift the soil under dam. Moreover, cracks are commonly formed in dams after construction. These cracks might produce several complications in the dam structure. Several investigations have shown the influence of the injected veil that made the dams stronger. This study shows the numerical results of the injection influence on a gravity dam. Finite element software is used to check up the best location of the injected veil and the maximum favorable depth. The obtained numerical results show the major effect of the veil injection on the uplift pressure force, the ground water values, and the flows pass under the gravity dam. HIGHLIGHTS The impact of this research can be summed up in these points.; Highlight on one of the major problems that affect the stability of gravity dam.; Clarify how to solve this problem and prevent the losses in different levels (Humans life and economic way).; Illustrate in an easy numerical method how to solve such severe problem.; Encourage the researchers to use the veil injection system in other dam types.;

Published

2022

20. 基于 MIDAS 和 LUSAS 有限元软件的 混凝土预制沉管水化热温度应力分析.

Author

陈飞翔, 明鑫, 张国志, 刘可心, and 舒腾飞

Abstract

Copyright of Bearing is the property of Bearing Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

21. Investigation of Strengthening Reinforced Concrete Beam-Column Connection Wrapped with Fiber-reinforced Polymer

Author

Rzgar A. Mohammed and Hersh F. Mahmood

Subjects

beam-column joints, finite element software, cfrp sheet, Science, Engineering (General). Civil engineering (General), TA1-2040

Abstract

In reinforced concrete structures, the beam-column connection area has a considerable influence on the behavior of the structure. The use of fiber-reinforced polymer FRP to strengthen the connections in the Reinforced structure can be one of the solutions to transform this area, thus improving the behavior of the structure, which is achieved through the use of fiber-reinforced polymer of carbon to achieve high-strength concrete beam-column connections Investigations have been conducted using finite element modeling. The concrete damage plasticity model has been used to analyze the model. The results show that the bearing capacity has developed considerably, but the ductility is also significantly reduced. The study also evaluated the qualities of various reinforcement models and proposed the most effective reinforcement model. The use of fiber-reinforced polymer in the flex zone with fibers oriented at forty-five degrees in the shear zone of the joint showed the most significant changes in behavior. The demolition of reinforced concrete beam-column joints is a sudden failure without prior notice, since the collapse of the column and the connection before the break of the beam are undesirable, their occurrence can cause irreparable damage.

Published

2022

22. Investigation on Behaviour of Alternate Roofing System Using Arch Panels

Author

Pooran, H. M., Renuka Devi, M. V., Basutkar, S. M., di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Raman, Sudharshan N., editor, Bhattacharjee, Bishwajit, editor, and Bhattacharjee, J., editor

Published

2021

23. Analytical Assessment on the Behaviour of Conical Shell Foundation

Author

Lamya, T., Sheeja, M. K., di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Dasgupta, Kaustubh, editor, Sudheesh, T. K., editor, Praseeda, K. I., editor, Unni Kartha, G., editor, Kavitha, P. E., editor, and Jawahar Saud, S., editor

Published

2021

24. Magnetic Field Analysis and Structure Optimization of Deflection Double Stator Switched Reluctance Generator

Author

Zhe Qian, Xueting Wang, Zheng Li, and Xuze Yu

Subjects

central composite design method (CCD), deflection double stator switched reluctance generator (DDSSRG), finite element software, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The deterioration of environment, the aggravation of energy crisis and the exhaustion of non renewable energy promote the development of green new energy. Among them, wind power generation has become a research hotspot in the field of new energy at home and abroad. In this paper, the deflection double stator switched reluctance generator (DDSSRG) is taken as the research object, the basic modelling and analysis of DDSSRG are carried out, and the magnetic field of the generator is analyzed by using the finite element software. The structure of the generator is optimized by using the central composite design method (CCD). Finally, the experimental platform of the generator is built to verify the feasibility of the theory in structure.

Published

2022

25. Seismo-VLAB: An open-source finite element software for seismic meso-scale simulations

Author

Danilo S. Kusanovic, Elnaz Seylabi, and Domniki Asimaki

Subjects

Finite element software, Soil–structure interaction, Wave propagation, Meso-scale simulation, Perfectly matched layer, Domain reduction method, Computer software, QA76.75-76.765

Abstract

We present Seismo-VLAB (SVL), a new open-source, object-oriented finite element software designed to optimize meso-scale simulations in the context of structural and geotechnical engineering. To this end, state-of-the-art tools and parallel computing capabilities required for efficient modeling of soil–structure interaction and wave propagation in heterogeneous half-spaces are included. For example, perfectly matched layer, domain reduction method, dynamic nonlinear solvers, cutting edge parallel linear system solvers, domain decomposition method, and a series of plasticity models are some of the features available in SVL. In this work, we present the numerical implementation and software structure so enthusiastic developers can contribute to this open-source project and showcase some software capabilities using an illustrative example.

Published

2023

26. 分节预制地下连续墙围护结构加固施工技术.

Author

田德胜

Subjects

BORED piles, DIAPHRAGM walls, CURTAIN walls, RETAINING walls, RANGE of motion of joints, UNDERGROUND construction, CONCRETE-filled tubes, HIGH strength steel

Abstract

Copyright of Fly Ash Comprehensive Utilization is the property of Hebei Fly Ash Comprehensive Utilization Magazine Co., Ltd. and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

27. 克里金模型用于预测聚能射流速度的方法研究.

Author

雷嫡宇, 王利侠, 寇鹏飞, and 薛 标

Subjects

SHAPED charges, KRIGING, COMPUTER simulation, VELOCITY, EXPLOSIVES, ANGLES

Abstract

Copyright of Chinese Journal of Explosives & Propellants is the property of Chinese Journal of Explosives & Propellants Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

28. Effect Of Boundary Conditions On Buckling Of Cylindrical Steel Tanks With Variable Thicknesses Under Local Settlement

Author

Sina Nassernia and H. Showkati

Subjects

variable thickness, cylindrical tanks, finite element software, local settlement, stiffening ring, Building construction, TH1-9745

Abstract

Cylindrical steel tanks have been used to store various materials and fluids. From a geometrical point of view, steel tanks have a very low thickness compared to the other two dimensions and thus are classified as thin-walled structures. Nowadays, the use of thin-walled structures is very popular. The main reason for this is the low weight and high strength of such structures. In order to reduce the weight and cost of the structure, cylindrical steel tanks can be made with variable thicknesses in height. Changing the thickness of the tank's wall has been considered to reduce weight and economic requirements. Settlement is one of the important issues that must be considered for reservoirs. In general, foundation settlement occurs under the tanks’ walls due to special soil properties, which are divided into three general components: Uniform, Tilt, and Local settlement. In the meantime, local settlement has the greatest impact on the tank’s shell, although it has the lowest value. This component can cause large radial displacements, shell buckling, and even tank’s failure. In this study, 17 steel cylindrical tanks with or without a reinforcing ring on the upper part were modeled in ABAQUS software and placed under local settlement at the edge of their floor. The values of settlement, equivalent buckling load, and their radial deformation were compared to each other. S4R elements (a four-node element with reduced curvature double integral) were used to mesh the tanks. The results of nonlinear analysis indicate that buckling occurs at the lower part of the shell. Moreover, the local settlement causes severe buckling at the site and perpendicular direction of the settlement. Appropriate and acceptable behavior of tanks with variable thickness in comparison with constant thickness and the hardening ring can have positive effects on the buckling behavior of tanks.

Published

2021

29. Geometrically Nonlinear Random Response of Stiffened Laminated Plates by Proper-Orthogonal-Decomposition-Based Reduced-Order Modeling.

Author

Shaochong Yang, Yuan Yao, Youchen Li, Lianhua Ma, Ying Zhang, and Qingsheng Yang

Abstract

The geometrically nonlinear random vibration response of stiffened laminated plates under acoustic excitation is carried out by using the equivalent linearization (EL) technique combined with the reduced-order model and the finite element method. The nonlinear equations of motion of stiffened laminated plates are obtained based on large deflection finite element formulation. The proper orthogonal decomposition technique is used to select the modal basis, and a reduced-order model of the structures is established. Based on the force error minimization approach, the EL formulation for solving nonlinear random vibration response is derived. Then the EL technique is incorporated into finite element software NASTRAN by the direct matrix abstraction program, and the direct matrix abstraction program also realizes the iterative process of determining the modal equivalent linear stiffness matrix. Then, the statistical dynamic response results obtained by EL and linear method are compared and analyzed. It is verified that the proposed method has high accuracy and efficiency, and it can be applied to the geometric nonlinear random vibration response analysis of stiffened laminated plates. The results show that geometric nonlinearity plays an important role in the vibration response of stiffened laminated plates, especially under high sound pressure loads. [ABSTRACT FROM AUTHOR]

Published

2022

30. An analysis of rainfall infiltration of expansive soil slope based on the finite element software custom constitutive model

Author

Hong RAO, Jinshu WANG, Zhiming ZHAO, Guang WU, and Tao FENG

Subjects

slope, expansive soil, shear strength formula, saturated-unsaturated seepage, water content, stability, finite element software, secondary development, Geology, QE1-996.5

Abstract

Under the condition of rainfall, the decrease in shear strength of a slope is one of the important factors that lead to the slope instability. Infiltration of rainwater into the slope is a dynamic process, and the water content or saturation of soil will change continuously. Therefore, it is of great significance to study the shear strength of soil under dynamic environment for real-time evaluation of the stability of soil slope under rainfall conditions. Based on the strength theory of unsaturated soil, this paper takes the expansive soil in the Jianshanying area of Guizhou Province as the object, combines the shear test data to establish the fitting relationship between the shear strength index and water content of the expansive soil, and puts forward the shear strength formula with water content as the variable. Based on the secondary development technology of ABAQUS platform, USDFLD subroutine is compiled to import the shear strength formula of the Jianshanying expansive soil, and the influence of strength attenuation and gravity change caused by the change of soil moisture content on the stability of the expansive soil slope under the condition of rainfall are also explored. The results show that with the increasing water content of the expansive soil, the particles in the soil expand by the absorbing water, the particle spacing decreases, and the adhesion between the mineral particles increases gradually. Until the water filling suction of the aggregate space decreases, the adhesion decreases rapidly, and the shear strength of the expansive soil decreases generally, in which the cohesion increases first and then decreases, and the internal friction angle decreases. The secondary development technology of ABAQUS software can realize the relationship of soil parameters with the change of water content, which provides a new technical means for the finite element analysis of unsaturated soil slope under the condition of rainfall.

Published

2021

31. Novel Ductile Enhancement in the Structural Characteristics of External Beam Column Joint with Potassium-Activated Green Concrete Technology.

Author

Rajendran, Mohana

Subjects

*GREEN roofs, *EARTHQUAKE resistant design, *ENERGY dissipation, *GREEN technology, *CYCLIC loads, *CONCRETE columns, *CONCRETE beams, *EARTHQUAKE zones, *ARTIFICIAL joints

Abstract

Ductility and energy dissipation capacity of the beam column joints are the two prominent characteristics which govern the stability of the entire structure constructed in the seismic prone areas. In this paper, the effect of potassium-activated geopolymer concrete in the exterior beam column joint application is investigated under low frequency cyclic loading. Numerical analysis has been done by using the finite element software Abaqus and compared with the experimental work. From the load deformation relationship, parametric studies are carried out in the aspects of ductility, stiffness degradation, energy dissipation capacity, drift ratio and cracking pattern. The use of potassium-activated geopolymer technology in the exterior beam column joint application resulted in the improved ductility, energy dissipation capacity with superior ultimate load carrying capacity of 1.05% over conventional cement reinforced concrete beam column joints with special confining reinforcement confirmed by IS 13920 due to the enormous polymerization activated by high molecular potassium ions. There is an improved energy dissipation capacity of 2.78% of potassium-based geopolymer specimen resulting in lesser number of non-structural cracks and 11.26% more deformation under 11.96% enlarged drift ratio than the conventional reinforced concrete specimen. From the observed results, it is clearly noted that the implementation of potassium-activated green polymer technology in the beam column joints possessed enhanced ductility characteristics to protect the structure susceptible to seismic environment and resulted in innovative, economical and sustainable mode of seismic-resistant building construction. [ABSTRACT FROM AUTHOR]

Published

2022

32. Effects of external shed damage on voltage and electric field profile for overhead insulators

Author

Rosli, Hanan, Othman, Nordiana Azlin, Mohd Jamail, Nor Akmal, and Ismail, Muhammad Nafis

Published

2019

33. Models of Active Bulk Composites and New Opportunities of the ACELAN Finite Element Package

Author

Kurbatova, N. V., Nadolin, D. K., Nasedkin, A. V., Nasedkina, A. A., Oganesyan, P. A., Skaliukh, A. S., Soloviev, A. N., Öchsner, Andreas, Series editor, da Silva, Lucas F. M., Series editor, Altenbach, Holm, Series editor, and Sumbatyan, Mezhlum A., editor

Published

2017

34. Analysis of Deflection in Isotropic and Orthotropic Rectangular Plates with Central Opening Under Transverse Static Loading

Author

Bouzgou, Ahmed Abdelatif, Tati, Abdelouahab, Khechai, Abdelhak, Boukharouba, Taoufik, editor, Pluvinage, Guy, editor, and Azouaoui, Krimo, editor

Published

2017

35. Vibration response test method of curtain wall under seismic coupling.

Author

Li, Jianbo

Abstract

Due to the seismic coupling effect, there is a big gap between the test results and the actual value, and the reliability is not high. Therefore, a test method for the vibration response of building curtain wall under the coupling effect of earthquake is studied. According to the relationship between the glass curtain wall and the main structure of the building, the differential equations of vibration response of the building curtain wall were constructed. During the process, the building and the curtain wall were divided, and the vibration response of the structural floor was obtained. Then, the vibration response of the floor was input into the curtain wall unit system between the floors, and the glass curtain wall response spectrum was established, and the vibration equation of the curtain wall was determined based on these. Taking Wuhan Railway Station as the study object, the finite element numerical value analytical model of the object was constructed by finite element software ANSYS14.0, and the influence of the natural vibration period of the structure, the natural vibration period of the curtain wall system, and the ground vibration on the coupled dynamic response of the curtain wall was studied. The results show that the vibration response of the glass curtain wall under seismic coupling is either amplified or weakened. The acceleration peak of the curtain wall usually appears when the two or three of the curtain wall natural vibration period, the structural natural vibration period, and the ground vibration period are close. Among them, the most dangerous situation is that the three are close. When the seismic magnitude is up to 9 degree, the structural stress of the curtain wall is less than the allowable value of the material, and it can be seen that the building structure is safe under this situation. [ABSTRACT FROM AUTHOR]

Published

2021

36. 基于有限元软件自定义本构模型的 膨胀土边坡降雨入渗分析.

Author

饶鸿, 王金淑, 赵志明, 吴光, and 冯涛

Abstract

Copyright of Hydrogeology & Engineering Geology / Shuiwendizhi Gongchengdizhi is the property of Hydrogeology & Engineering Geology Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2021

37. Modelling and analysis of the effects of cutting of core laminations in electric machines.

Author

Alatawneh, Natheer, Saleem, Aroba, Rahman, Tanvir, Lowther, David A., and Chromik, Richard

Abstract

Experimental measurements of electrical machine performances reveal a significant difference between simulations and measurements. It is known that the manufacturing processes of machines, particularly, the cutting of core laminations adversely affects material properties. The current techniques for considering the effects of cutting lack accuracy, computation efficiency and applicability for finite element (FE) software. This study proposes a method to model the variation in the magnetic properties of electrical steel due to cutting based on a non‐equal multi‐slice technique. In this work, the method has been validated and implemented on a FE permanent magnet synchronous motor model. Also, the proposed method has been compared with the single‐layer method. [ABSTRACT FROM AUTHOR]

Published

2020

38. 基于逐点去约束法的索桁张拉结构形状判定及自应力模态求解方法.

Author

薛素铎, 鲁建, 李雄彦, and 刘人杰

Abstract

Copyright of Advanced Engineering Science / Gongcheng Kexue Yu Jishu is the property of Advanced Engineering Science Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

39. Process-Integrated Heat Treatment of Hot Forged Components

Author

Huskic, Adis, Kazhai, Mohammad, Behrens, Bernd-Arno, Tekkaya, A. Erman, editor, Homberg, Werner, editor, and Brosius, Alexander, editor

Published

2015

40. Behavior Analysis of Cold Expanded-Bolt Clamped AL2024-T3 Plate

Author

M. Sayah Badkhor, A. R. Naddaf Oskouei, H. Mohammadi Hooyeh, and F. Shirbakht

Subjects

al2024-t3, bolt clamping, cold expansion, finite element software, fatigue life, Technology

Abstract

For making rivet and bolt connections, making a hole is necessary. While basic S-N graph can be extracted from design documents, analysis of stress can be used for two different approaches. The first approach is the theoretical derivation of analytical relations with simplified assumptions like planar stress or uniform bolt load distribution. The other one is the numerical simulation using robust codes like Abaqus software. By using these two approaches, residual stress distribution around the hole can be extracted in various conditions. In this experiment, an aluminium 2024-T3 plate with 3.2 mm thickness is considered. The stress analysis results and basic S-N graph were combined and discursive S-N graphs were obtained for different cold-expanded bolted holes. These graphs were compared with experimental data in several steps. First, the bolt fastening was considered. In the second step, cold expansion was considered and in the final step, the effects of fastening bolts and nuts and cold expansion was considered simultaneously. At last, a comparison between various steps was drawn. The results of this study showed that this new analytical method on distribution of residual stresses around cold expansion holes is as effectiveness as old methods.

Published

2017

41. Harmonic Flux Distribution in Transformer Based on Harmonic-Balance Finite Element Method

Author

Hu, Qiang, Luo, Derong, Wang, Yong, SAE-China, FISITA, Xing, Song, editor, Chen, Suting, editor, Wei, Zhanming, editor, and Xia, Jingming, editor

Published

2014

42. Multi-step diferansiyel transform metodu ile uç kütle eklentili kirişlerin serbest titreşim analizi.

Author

Katı, Hilal Doğanay and Gökdağ, Hakan

Abstract

Dynamic analysis of beam-tip mass systems is a significant issue in terms of providing successful design of mechanisms such as robot arms and manipulators. In the relevant literature, uniform beams have been mostly considered for the free vibration analysis of these systems whereas the number of studies using nonuniform beam is limited. Furthermore, center of tip mas is, in general, coincident with the attachment point of the beam, and the tip mass is assumed to be a point mass. This research concerns a non-uniform beam with a three dimensional rigid tip mass whose center of gravity is not coincident with the attachment point of the beam and subjected to both torsional and flexural deformations in two orthogonal planes. A semi-numerical method called Multi-Step Differential Transform Method (MDTM) is employed for the solution of governing equations of the system. Natural frequencies and mode shapes of the system are obtained for two different boundary conditions, i.e. the left end clamped or free. The influence of tip mass dimensions, beam length and taper ratio on the natural frequencies are studied, and the well-known finite element software (ANSYS) is employed to compare the results and confirm the accuracy of the model. It is proved that results obtained by MDTM and ANSYS are sufficiently close to each other. [ABSTRACT FROM AUTHOR]

Published

2019

43. Simulation and Analysis of Mechanical Behavior of Groove-Shaped Over-Squeezing During Mechanical Ruling.

Author

Shi, Chaochao, Shi, Guangfeng, Shi, Guoquan, and Li, Haichao

Abstract

The single crystal diamond chisel-edge tool is used to machine the 79 g/mm echelle diffraction grating, which is used as the research background. DEFORM-3D finite element software is used to simulate the mechanical ruling grating processing, and the influence of the parameters of the ruling tool on the squeezing force of aluminum film material is obtained. By analyzing the flow law of several sampling points in the groove-shaped over-squeezing region, the slip deformation characteristics of the aluminum film during the groove-shaped over-squeezing are clarified. Moreover, the velocity and stress field of aluminum film are analyzed under groove over-squeezing phenomenon. Therefore, it provides a basis for predicting the phenomenon of groove-shaped over-squeezing in the mechanical ruling grating processing. [ABSTRACT FROM AUTHOR]

Published

2019

44. LiToTac: An Interactive-Interface Software for Finite Element Analysis of Multiple Contact Dynamics.

Author

Lei Peng, Zhiqiang Feng, Joli, Pierre, and Renaud, Christine

Subjects

FINITE element method software, CONTACT mechanics, OBJECT-oriented methods (Computer science), ANSYS (Computer system), COMPUTATIONAL mechanics

Abstract

In order to investigate the mechanical behavior of systems with complex architecture and a large number of contacting bodies, a finite element software, named LiToTac, has been developed by using the object-oriented programming technique. This software, with an interactive graphical user interface, is able to handle highly non-linear problems including multiple contacts and large deformation. More importantly, the contact detection based on a hybrid three-stages methodology can be performed automatically, which is more efficient than the common strategies of pre-defining contact zones in commercial FEM software like ANSYS, ABAQUS, etc. In addition, the contact solver in LiToTac is portable between dynamic and quasi-static codes and can accurately solve contact coupled with friction in a reduced system. Several numerical examples are carried out to illustrate the functionality and capacity of the software package. [ABSTRACT FROM AUTHOR]

Published

2019

45. Numerical study on transverse deformation characteristics of shield tunnel subject to local soil loosening

Author

Weijie Chen, Pang Xiaochao, Huang Maolong, Dong Su, Chen Xiangsheng, and Xuetao Wang

Subjects

Materials science, Transverse deformation, Finite element software, Shield tunnel, Building and Construction, Coefficient of subgrade reaction, Engineering geology. Rock mechanics. Soil mechanics. Underground construction, Deformation (meteorology), Force balance, Geotechnical Engineering and Engineering Geology, Equivalent stiffness, Shield, Bending moment, Model test, TA703-712, Transverse shear deformation, Geotechnical engineering, Civil and Structural Engineering, Numerical analysis, Soil loosening

Abstract

In this study, a refined numerical model for segmental lining of a shield tunnel, which contains detailed models of reinforcement and connecting bolts, is established using finite element software. The model is first validated by the results from a full-scale model test. Then, based on the load-structure method, this numerical model is adopted to investigate the internal force distribution and the transverse deformation characteristics of the shield tunnel when it is subject to local soil loosening. The influence of loosening position, loosening range, and loosening extent on the mechanical response is extensively studied through comprehensive numerical analyses. The results show that the main influence of local soil loosening on the ring is to disturb the force balance and change the constraint conditions, thus changing the deformation pattern and force state. After the loosening occurs, the bending moment of the ring in the loosening range increases and the axial force decreases. The vertical convergence of the ring is the largest and the equivalent stiffness of the ring is the smallest when the local soil loosened at the haunch and the loosening range α is 90°. The vertical convergence of the ring increases with increasing of the loosening extent, and the equivalent stiffness decreases linearly with increasing of the loosening extent. The results can enhance our understanding of mechanical behaviors of segmental lining associated soil loosening, and will show a possible way for detecting soil loosening based on the measured deformation and internal forces.

Published

2022

46. Using Plaxis 2D finite element modeling to assess bearing capacity of Sultana’s soil in Najran Region, Kingdom of Saudi Arabia

Author

Gamil M.S. Abdullah

Subjects

Embedment, Finite element software, Numerical analysis, Linear elasticity, Foundation (engineering), Geotechnical engineering, General Medicine, Bearing capacity, Terzaghi's principle, Finite element method, Geology

Abstract

In this paper, a numerical model was developed using finite element software, Plaxis 2D, to assess the bearing capacity of the Sultana's soil in Najran Region, Saudi Arabia. The square foundation (2 m × 2 m) resting on the ground surface and at 1.5 m depth of embedment was modeled and analyzed. The predicted bearing capacity was compared and validated with the bearing capacity calculated from some literature theories such as Terzaghi, Meyerhof, Hansen, Vesic, and AASHTO. The analysis was performed using Mohr-Coulomb's criterion model for soil medium and linear elastic for footing. The footing was modeled as a flexible footing. Soil parameters used in the numerical modeling were calculated from field and lab tests conducted on the research area's soil. The numerical analysis results showed that the outcomes of Plaxis 2D modeling are in a close range with the Terzaghi, Meyerhof, Hansen, Vesic, and AASHTO formulas results. However, a little bit high difference was noticed between the Plaxis 2D and Terzaghi results where the foundation was placed at 1.5 m embedment depth.

Published

2022

47. Experimental and numerical study of continuous span concrete composite slabs

Author

Wang Mengmeng, Jie Liu, Zhen-shan Wang, Jian-bo Tian, Zhang Junfa, and Hong-chao Guo

Subjects

Materials science, Finite element software, business.industry, Composite number, Physics::Optics, Building and Construction, Structural engineering, Physics::Classical Physics, Span (engineering), Finite element method, Shear (sheet metal), Flexural strength, Physics::Plasma Physics, Architecture, Slab, Safety, Risk, Reliability and Quality, business, Beam (structure), Civil and Structural Engineering

Abstract

Vertical static loading tests were carried out on two kinds of continuous span concrete composite slabs with beam and slab connected by studs and open-hole folding plate connectors. Combined with the test results, on the basis of the analysis of load–deflection curves and load-reinforcement strain curves, the finite element software ABAQUS was used for the numerical study of the continuous span concrete composite slabs. The plate thickness, concrete strength, thickness of the shear key and slab span has carried on the finite element analysis. The results show that the strength of the concrete and the thickness of the shear bond have little effect on the flexural performance of the continuous span concrete composite slab, but the shear bond can strengthen the connection between the slab and the steel beam and reduce the sliding and lifting of the composite slab on the steel beam. The slab thickness and slab span have a great influence on the flexural performance of continuous span concrete composite slabs. The peak load of the specimen increases with the increase of slab thickness and decreases with the increase of slab span. This study will provide a theoretical basis for future design and engineering application of composite slabs.

Published

2021

48. Seismic performance analysis and rehabilitation applications for a historical masonry building through field works and experimental investigations

Author

Baris Yildizlar

Subjects

Structure (mathematical logic), Rehabilitation, business.industry, Computer science, Finite element software, medicine.medical_treatment, Building and Construction, Masonry, Field (computer science), Construction engineering, Lateral bending, Work (electrical), Architecture, medicine, Safety, Risk, Reliability and Quality, business, Civil and Structural Engineering

Abstract

Historical buildings are distinct structures in terms of seismic performance and extensive evaluations focusing on their seismic mechanisms and responses have yet to be clarified and presented. Thus, it was aimed to present a methodology consisting of various analysis approaches for historical buildings to increase the seismic strength. This study also covers rehabilitation applications for a historical masonry structure that was originally designed as the hospital building, however, later refunctioned to serve as the military prison, and presently in use as a university building. The pre-defined tasks in the study are implemented in three stages. Firstly, the material properties of building components were determined through field study and laboratory tests. Secondly, a series of simulations such as linear, non-linear, and kinematic analyses were performed using finite element software. As a result of the analysis, it was determined that the structure did not satisfy the targeted performance levels, as well as vertical and lateral bending mechanisms emerged. Therefore, a rehabilitation stage is presented due to the unsatisfactory seismic strength of the building. This work examines the seismic performance and proposes a rehabilitation approach for masonry buildings focusing on a particular and significant case, which includes the first structure built using solid bricks in Istanbul in the Ottoman era.

Published

2021

49. Influence of tower anticorrosion coating as contaminant on operation characteristics of composite insulator

Author

Mei Hongwei, Guan Xiyuan, Fu Xiangyun, Zhao Chenglong, and Wang Liming

Subjects

hydrophobicity, silicone rubber, insulator testing, poles and towers, flashover, vulcanisation, corrosion protective coatings, finite element analysis, composite insulators, insulator contamination, high-temperature effects, operation characteristics, hydrophobicity transfers, anticorrosion coatings, high-temperature vulcanised silicone rubber, rust-based corrosion, transmission towers, mechanical properties, pollution flashover voltage, finite element software, electric field distribution, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Electricity, QC501-721

Abstract

Anticorrosion coatings are commonly applied to prevent rust-based corrosion in transmission towers. Unfortunately, anticorrosion coatings may drip onto the surface of composite insulators during the construction process, which is likely to do harm to operation characteristics of composite insulators. This Letter was conducted to determine the influence of anticorrosion coatings on composite insulator performance. The mechanical properties, hydrophobicity, hydrophobic transfer, and flashover voltage of high-temperature vulcanised (HTV) silicone rubber specimens with and without the coating were investigated in detail. Appropriate solutions for avoiding unwanted effects on insulator performance are proposed accordingly. The influence of coating on the pollution flashover voltage of the composite insulator was also determined by changing the type, area, and shape of coating attached to the insulator surface. Finite element software was also used to analyse the effects of coatings on the electric field distribution of the composite insulator. The coating slightly affects the mechanical properties of HTV silicone rubber, but significantly impacts its hydrophobicity and hydrophobicity transfer. The pollution flashover characteristics of test composite insulators covered with the anticorrosion coating are also worst than those without coating.

Published

2018

50. Detection System Development of Drill Pipe Thread Based on ACFM Technique

Author

Guoming Chen, Xiao Li, Zhao Jianming, Xiaokang Yin, Jianxi Ding, Liu Xiangyang, Xin'an Yuan, and Wei Li

Subjects

System development, Drill, business.industry, Finite element software, Drill pipe, Structural engineering, Thread (computing), Signal, Finite element method, Stress (mechanics), Electrical and Electronic Engineering, business, Instrumentation, Geology

Abstract

As an important connection method between drill pipes, the thread is prone to fatigue cracks and stress corrosion cracks due to long-term exposure to complex forces and corrosive environments. The thread crack detection system of drill pipe based on altering current field measurement (ACFM) is proposed. The crack detection model of the drill pipe thread using ACFM is developed by the finite element software COMSOL. The distribution of the induced magnetic field above the thread is extracted. The relationships between the characteristic signal and the depth and angle of the crack are analyzed. The drill pipe thread detection probes and the detection system are established, and different types of cracks on two different specifications of threads are detected. The experimental results show that the detection system can achieve full coverage detection of the thread crest and root, and cracks at different angle can be identified effectively on the thread.

Published

2021