Your search keyword '"Jun-Yi Sun"' showing total 41 results

1. Improved Power Series Solution of Transversely Loaded Hollow Annular Membranes: Simultaneous Modification of Out-of-Plane Equilibrium Equation and Radial Geometric Equation

Author

Xiao-Ting He, Fei-Yan Li, and Jun-Yi Sun

Subjects

annular membrane, transverse loading, large deflection, power series solution, bending-free shell of revolution, Mathematics, QA1-939

Abstract

The ability to accurately predict the shape of a transversely loaded hollow annular membrane is essential to the design of bending-free hollow annular shells of revolution, which requires a further improvement in the hollow annular membrane solution to meet the needs of this accurate prediction. In this paper, the large deflection problem of a transversely loaded hollow annular membrane is reformulated by simultaneously modifying the out-of-plane equilibrium equation and radial geometric equation, and a newer and more refined power series solution is derived. The reason why the classical radial geometry equation induces errors is revealed. The convergence and asymptotic behavior of the power series solution obtained is analyzed numerically. The newly derived solution is compared with the two previously derived solutions graphically, showing that the newly derived solution performs basically as well as expected. In addition, the anticipated use of the hollow and not-hollow annular membrane solutions for the design application of bending-free annular shells of revolution is discussed.

Published

2023

2. An Improved Mathematical Theory for Designing Membrane Deflection-Based Rain Gauges

Author

Jun-Yi Sun, Ning Li, and Xiao-Ting He

Subjects

conductive membrane, transversely loading, axisymmetric deformation, large deflection, power-series solution, Mathematics, QA1-939

Abstract

This paper is devoted to developing a more refined mathematical theory for designing the previously proposed membrane deflection-based rain gauges. The differential-integral equations governing the large deflection behavior of the membrane are improved by modifying the geometric equations, and more accurate power-series solutions of the large deflection problem are provided, resulting in a new and more refined mathematical theory for designing such rain gauges. Examples are presented to illustrate how to analyze the convergence of the power-series solutions and how to numerically calibrate membrane deflection-based linear rain gauges. In addition, some important issues are demonstrated, analyzed, and discussed, such as the superiority of the new mathematical theory over the old one, the reason why the classical geometric equations cause errors, and the influence of changing design parameters on the input–output relationships of rain gauges.

Published

2023

3. An Exact In-Plane Equilibrium Equation for Transversely Loaded Large Deflection Membranes and Its Application to the Föppl-Hencky Membrane Problem

Author

Jun-Yi Sun, Ji Wu, Xue Li, and Xiao-Ting He

Subjects

large deflection membrane, transverse uniform loading, axisymmetric deformation, in-plane equilibrium equation, power series solution, Mathematics, QA1-939

Abstract

In the existing literature, there are only two in-plane equilibrium equations for membrane problems; one does not take into account the contribution of deflection to in-plane equilibrium at all, and the other only partly takes it into account. In this paper, a new and exact in-plane equilibrium equation is established by fully taking into account the contribution of deflection to in-plane equilibrium, and it is used for the analytical solution to the well-known Föppl-Hencky membrane problem. The power series solutions of the problem are given, but in the form of the Taylor series, so as to overcome the difficulty in convergence. The superiority of using Taylor series expansion over using Maclaurin series expansion is numerically demonstrated. Under the same conditions, the newly established in-plane equilibrium equation is compared numerically with the existing two in-plane equilibrium equations, showing that the new in-plane equilibrium equation has obvious superiority over the existing two. A new finding is obtained from this study, namely, that the power series method of using Taylor series expansion is essentially different from that of using Maclaurin series expansion; therefore, the recurrence formulas for power series coefficients of using Maclaurin series expansion cannot be derived directly from that of using Taylor series expansion.

Published

2023

4. Variational Solution and Numerical Simulation of Bimodular Functionally Graded Thin Circular Plates under Large Deformation

Author

Xiao-Ting He, Xiao-Guang Wang, Bo Pang, Jie-Chuan Ai, and Jun-Yi Sun

Subjects

variational solution, numerical simulation, bimodular effect, functionally graded materials, thin circular plate, large deformation, Mathematics, QA1-939

Abstract

In this study, the variational method and numerical simulation technique were used to solve the problem of bimodular functionally graded thin plates under large deformation. During the application of the variational method, the functional was established on the elastic strain energy of the plate while the variation in the functional was realized by changing undetermined coefficients in the functional. As a result, the classical Ritz method was adopted to obtain the important relationship between load and maximum deflection that is of great concern in engineering design. At the same time, the numerical simulation technique was also utilized by applying the software ABAQUS6.14.4, in which the bimodular effect and functionally graded properties of the materials were simulated by subareas in tension and compression, as well as the layering along the direction of plate thickness, respectively. This study indicates that the numerical simulation results agree with those from the variational solution, by comparing the maximum deflection of the plate, which verifies the validity of the variational solution obtained. The results presented in this study are helpful for the refined analysis and optimization design of flexible structures, which are composed of bimodular functionally graded materials, while the structure is under large deformation.

Published

2023

5. Functionally Graded Thin Circular Plates with Different Moduli in Tension and Compression: Improved Föppl–von Kármán Equations and Its Biparametric Perturbation Solution

Author

Xiao-Ting He, Bo Pang, Jie-Chuan Ai, and Jun-Yi Sun

Subjects

biparametric perturbation, Föppl–von Kármán equation, bimodular materials, functionally graded materials, circular plate, Mathematics, QA1-939

Abstract

The biparametric perturbation method is applied to solve the improved Föppl–von Kármán equation, in which the improvements of equations come from two different aspects: the first aspect concerns materials, and the other is from deformation. The material considered in this study has bimodular functionally graded properties in comparison with the traditional materials commonly used in classical Föppl–von Kármán equations. At the same time, the consideration for deformation deals with not only the large deflection as indicated in classical Föppl–von Kármán equations, but also the larger rotation angle, which is incorporated by adopting the precise curvature formulas but not the simple second-order derivative term of the deflection. To fully demonstrate the effectiveness of the biparametric perturbation method proposed, two sets of parameter combinations, one being a material parameter with central defection and the other being a material parameter with load, are used for the solution of the improved Föppl–von Kármán equations. Results indicate that not only the two sets of solutions from different parameter combinations are consistent, but also they may be reduced to the single-parameter perturbation solution obtained in our previous study. The successful application of the biparametric perturbation method provides new ideas for solving similar nonlinear differential equations.

Published

2022

6. Solution of the Thermoelastic Problem for a Two-Dimensional Curved Beam with Bimodular Effects

Author

Xiao-Ting He, Meng-Qiao Zhang, Bo Pang, and Jun-Yi Sun

Subjects

thermoelasticity, bimodular effect, curved beams, tension and compression, thermal stress, Mathematics, QA1-939

Abstract

In classical thermoelasticity, the bimodular effect of materials is rarely considered. However, all materials will present, in essence, different properties in tension and compression, more or less. The bimodular effect is generally ignored only for simple analysis. In this study, we theoretically analyze a two-dimensional curved beam with a bimodular effect and under mechanical and thermal loads. We first establish a simplified model on a subarea in tension and compression. On the basis of this model, we adopt the Duhamel similarity theorem to change the initial thermoelastic problem as an elasticity problem without the thermal effect. The superposition of the special solution and supplement solution of the Lamé displacement equation enables us to satisfy the boundary conditions and stress continuity conditions of the bimodular curved beam, thus obtaining a two-dimensional thermoelastic solution. The results indicate that the solution obtained can reduce to bimodular curved beam problems without thermal loads and to the classical Golovin solution. In addition, the bimodular effect on thermal stresses is discussed under linear and non-linear temperature rise modes. Specially, when the compressive modulus is far greater than the tensile modulus, a large compressive stress will occur at the inner edge of the curved beam, which should be paid with more attention in the design of the curved beams in a thermal environment.

Published

2022

7. A Refined Closed-Form Solution for Laterally Loaded Circular Membranes in Frictionless Contact with Rigid Flat Plates: Simultaneous Improvement of Out-of-Plane Equilibrium Equation and Geometric Equation

Author

Fei-Yan Li, Xue Li, Qi Zhang, Xiao-Ting He, and Jun-Yi Sun

Subjects

circular membranes, large deflections, plate/membrane contact, power series method, closed-form solution, Mathematics, QA1-939

Abstract

Essential to the design and development of circular contact mode capacitive pressure sensors is the ability to accurately predict the contact radius, maximum stress, and shape of a laterally loaded circular membrane in frictionless contact with a concentric circular rigid flat plate. In this paper, this plate/membrane contact problem is solved analytically again by simultaneously improving both out-of-plane equilibrium equation and geometric equation, and a new and more refined closed-form solution is given to meet the need of accurate prediction. The new closed-form solution is numerically discussed in convergence and effectiveness and compared with the previous one, showing that it can greatly improve the prediction accuracy of the contact radius, maximum stress, and shape of the circular membrane in frictionless contact with the rigid flat plate.

Published

2022

8. A Refined Closed-Form Solution for the Large Deflections of Alekseev-Type Annular Membranes Subjected to Uniformly Distributed Transverse Loads: Simultaneous Improvement of Out-of-Plane Equilibrium Equation and Geometric Equation

Author

Bo Li, Qi Zhang, Xue Li, Xiao-Ting He, and Jun-Yi Sun

Subjects

annular membrane, uniform transverse loading, large deflection, power series method, closed-form solution, Mathematics, QA1-939

Abstract

The Alekseev-type annular membranes here refer to annular membranes fixed at outer edges and connected with a movable, weightless, stiff, con-centric, circular thin plate at inner edges, which were proposed originally by Alekseev for bearing centrally concentrated loads. They are used to bear the pressure acting on both membranes and plates, which was proposed originally in our previous work for developing pressure sensors. The pressure is applied onto an Alekseev-type annular membrane, resulting in the parallel movement of the circular thin plate. Such a movement can be used to develop a capacitive pressure sensor using the circular thin plate as a movable electrode plate of a parallel plate capacitor. The pressure applied can be determined by measuring the change in capacitance of the parallel plate capacitor, based on the closed-form solution for the elastic behavior of Alekseev-type annular membranes. However, the previous closed-form solution is unsuitable for annular membranes with too large deflection, which limits the range of pressure operation of the developed sensors. A new and more refined closed-form solution is presented here by improving simultaneously the out-of-plane equilibrium equation and geometric equation, making it possible to develop capacitive pressure sensors with a wide range of pressure operations. The new closed-form solution is numerically discussed in its convergence and effectiveness and compared with the previous one. Additionally, its beneficial effect on developing the proposed capacitive pressure sensors is illustrated.

Published

2022

9. One- and Two-Dimensional Analytical Solutions of Thermal Stress for Bimodular Functionally Graded Beams under Arbitrary Temperature Rise Modes

Author

Xuan-Yi Xue, Si-Rui Wen, Jun-Yi Sun, and Xiao-Ting He

Subjects

functionally graded beams, bimodular effect, thermoelasticity, thermal stress, tension and compression, Mathematics, QA1-939

Abstract

In this study, we analytically solved the thermal stress problem of a bimodular functionally graded bending beam under arbitrary temperature rise modes. First, based on the strain suppression method in a one-dimensional case, we obtained the thermal stress of a bimodular functionally graded beam subjected to bending moment under arbitrary temperature rise modes. Using the stress function method based on compatibility conditions, we also derived two-dimensional thermoelasticity solutions for the same problem under pure bending and lateral-force bending, respectively. During the solving, the number of unknown integration constants is doubled due to the introduction of bimodular effect; thus, the determination for these constants depends not only on the boundary conditions, but also on the continuity conditions at the neutral layer. The comparisons indicate that the one- and two-dimensional thermal stress solutions are consistent in essence, with a slight difference in the axial stress, which exactly reflects the distinctions of one- and two-dimensional problems. In addition, the temperature rise modes in this study are not explicitly indicated, which further expands the applicability of the solutions obtained. The originality of this work is that the one- and two-dimensional thermal stress solutions for bimodular functionally graded beams are derived for the first time. The results obtained in this study may serve as a theoretical reference for the analysis and design of beam-like structures with obvious bimodular functionally graded properties in a thermal environment.

Published

2022

10. Revisiting the Boundary Value Problem for Uniformly Transversely Loaded Hollow Annular Membrane Structures: Improvement of the Out-of-Plane Equilibrium Equation

Author

Qi Zhang, Xue Li, Xiao-Ting He, and Jun-Yi Sun

Subjects

annular membrane, uniform transverse loading, axisymmetric deformation, large deflection, power series method, closed-form solution, Mathematics, QA1-939

Abstract

In a previous work by the same authors, a hollow annular membrane structure loaded transversely and uniformly was proposed, and its closed-form solution was presented; its anticipated use is for designing elastic shells of revolution. Since the height–span ratio of shells of revolution is generally desired to be as large as possible, to meet the need for high interior space, especially for the as-small-as-possible horizontal thrust at the base of shells of revolution, the closed-form solution should be able to cover annular membranes with a large deflection–outer radius ratio. However, the previously presented closed-form solution cannot meet such an ability requirement, because the previous out-of-plane equilibrium equation used the assumption of a small deflection–outer radius ratio. In this study, the out-of-plane equilibrium equation is re-established without the assumption of a small deflection–outer radius ratio, and a new and more refined closed-form solution is presented. The new closed-form solution is numerically discussed regarding its convergence and effectiveness, and compared with the old one. The new and old closed-form solutions agree quite closely for lightly loaded cases but diverge as the load intensifies. Differences in deflections, especially in stresses, are very significant when the deflection–outer radius ratio exceeds 1/4, indicating that, in this case, the new closed-form solution should be adopted in preference to the old one.

Published

2022

11. A Closed-Form Solution without Small-Rotation-Angle Assumption for Circular Membranes under Gas Pressure Loading

Author

Xiao-Ting He, Xue Li, Bin-Bin Shi, and Jun-Yi Sun

Subjects

circular membrane, gas pressure loading, large deflection, power series method, closed-form solution, Mathematics, QA1-939

Abstract

The closed-form solution of circular membranes subjected to gas pressure loading plays an extremely important role in technical applications such as characterization of mechanical properties for freestanding thin films or thin-film/substrate systems based on pressured bulge or blister tests. However, the only two relevant closed-form solutions available in the literature are suitable only for the case where the rotation angle of membrane is relatively small, because they are derived with the small-rotation-angle assumption of membrane, that is, the rotation angle θ of membrane is assumed to be small so that “sinθ = 1/(1 + 1/tan2θ)1/2” can be approximated by “sinθ = tanθ”. Therefore, the two closed-form solutions with small-rotation-angle assumption cannot meet the requirements of these technical applications. Such a bottleneck to these technical applications is solved in this study, and a new and more refined closed-form solution without small-rotation-angle assumption is given in power series form, which is derived with “sinθ = 1/(1 + 1/tan2θ)1/2”, rather than “sinθ = tanθ”, thus being suitable for the case where the rotation angle of membrane is relatively large. This closed-form solution without small-rotation-angle assumption can naturally satisfy the remaining unused boundary condition, and numerically shows satisfactory convergence, agrees well with the closed-form solution with small-rotation-angle assumption for lightly loaded membranes with small rotation angles, and diverges distinctly for heavily loaded membranes with large rotation angles. The confirmatory experiment conducted shows that the closed-form solution without small-rotation-angle assumption is reliable and has a satisfactory calculation accuracy in comparison with the closed-form solution with small-rotation-angle assumption, particularly for heavily loaded membranes with large rotation angles.

Published

2021

12. Large Deformation Problem of Bimodular Functionally-Graded Thin Circular Plates Subjected to Transversely Uniformly-Distributed Load: Perturbation Solution without Small-Rotation-Angle Assumption

Author

Xue Li, Xiao-Ting He, Jie-Chuan Ai, and Jun-Yi Sun

Subjects

bimodular functionally graded materials, thin circular plate, large deformation, small-rotation-angle assumption, perturbation method, Mathematics, QA1-939

Abstract

In this study, the large deformation problem of a functionally-graded thin circular plate subjected to transversely uniformly-distributed load and with different moduli in tension and compression (bimodular property) is theoretically analyzed, in which the small-rotation-angle assumption, commonly used in the classical Föppl–von Kármán equations of large deflection problems, is abandoned. First, based on the mechanical model on the neutral layer, the bimodular functionally-graded property of materials is modeled as two different exponential functions in the tensile and compressive zones. Thus, the governing equations of the large deformation problem are established and improved, in which the equation of equilibrium is derived without the common small-rotation-angle assumption. Taking the central deflection as a perturbation parameter, the perturbation method is used to solve the governing equations, thus the perturbation solutions of deflection and stress are obtained under different boundary constraints and the regression of the solution is satisfied. Results indicate that the perturbation solutions presented in this study have higher computational accuracy in comparison with the existing perturbation solutions with small-rotation-angle assumption. Specially, the computational accuracies of external load and yield stress are improved by 17.22% and 28.79% at most, respectively, by the numerical examples. In addition, the small-rotation-angle assumption has a great influence on the yield stress at the center of the bimodular functionally-graded circular plate.

Published

2021

13. Axisymmetric Large Deflection Elastic Analysis of Hollow Annular Membranes under Transverse Uniform Loading

Author

Jun-Yi Sun, Qi Zhang, Xue Li, and Xiao-Ting He

Subjects

annular membrane, uniform transverse loading, structural analysis, large deflection, power series method, closed-form solution, Mathematics, QA1-939

Abstract

The anticipated use of a hollow linearly elastic annular membrane for designing elastic shells has provided an impetus for this paper to investigate the large deflection geometrically nonlinear phenomena of such a hollow linearly elastic annular membrane under transverse uniform loads. The so-called hollow annular membranes differ from the traditional annular membranes available in the literature only in that the former has the inner edge attached to a movable but weightless rigid concentric circular ring while the latter has the inner edge attached to a movable but weightless rigid concentric circular plate. The hollow annular membranes remove the transverse uniform loads distributed on “circular plate” due to the use of “circular ring” and result in a reduction in elastic response. In this paper, the large deflection geometrically nonlinear problem of an initially flat, peripherally fixed, linearly elastic, transversely uniformly loaded hollow annular membrane is formulated, the problem formulated is solved by using power series method, and its closed-form solution is presented for the first time. The convergence and effectiveness of the closed-form solution presented are investigated numerically. A comparison between closed-form solutions for hollow and traditional annular membranes under the same conditions is conducted, to reveal the difference in elastic response, as well as the influence of different closed-form solutions on the anticipated use for designing elastic shells.

Published

2021

14. A Two-Dimensional Thermoelasticity Solution for Bimodular Material Beams under the Combination Action of Thermal and Mechanical Loads

Author

Si-Rui Wen, Xiao-Ting He, Hao Chang, and Jun-Yi Sun

Subjects

thermoelasticity, bimodular material beams, thermal load, tension and compression, neutral layer, Mathematics, QA1-939

Abstract

A typical characteristic of bimodular material beams is that when bending, the neutral layer of the beam does not coincide with its geometric middle surface since the mechanical properties of materials in tension and compression are different. In the classical theory of elasticity, however, this characteristic has not been considered. In this study, a bimodular simply-supported beam under the combination action of thermal and mechanical loads is theoretically analyzed. First, a simplified mechanical model concerning the neutral layer is established. Based on this mechanical model, Duhamel’s theorem is used to transform the thermoelastical problem into a pure elasticity problem with imaginary body force and surface force. In solving the governing equation expressed in terms of displacement, a special solution of the displacement equation is found first, and then by utilizing the stress function method based on subarea in tension and compression, a supplement solution for the displacement governing equation without the thermal effect is derived. Lastly, the special solution and supplement solution are superimposed to satisfy boundary conditions, thus obtaining a two-dimensional thermoelasticity solution. In addition, the bimodular effect and temperature effect on the thermoelasticity solution are illustrated by computational examples.

Published

2021

15. Steady Fluid–Structure Coupling Interface of Circular Membrane under Liquid Weight Loading: Closed-Form Solution for Differential-Integral Equations

Author

Xue Li, Jun-Yi Sun, Xiao-Chen Lu, Zhi-Xin Yang, and Xiao-Ting He

Subjects

circular membrane, fluid-structure interaction, differential-integral equations, power series method, closed-form solution, Mathematics, QA1-939

Abstract

In this paper, the problem of fluid–structure interaction of a circular membrane under liquid weight loading is formulated and is solved analytically. The circular membrane is initially flat and works as the bottom of a cylindrical cup or bucket. The initially flat circular membrane will undergo axisymmetric deformation and deflection after a certain amount of liquid is poured into the cylindrical cup. The amount of the liquid poured determines the deformation and deflection of the circular membrane, while in turn, the deformation and deflection of the circular membrane changes the shape and distribution of the liquid poured on the deformed and deflected circular membrane, resulting in the so-called fluid-structure interaction between liquid and membrane. For a given amount of liquid, the fluid-structure interaction will eventually reach a static equilibrium and the fluid-structure coupling interface is steady, resulting in a static problem of axisymmetric deformation and deflection of the circular membrane under the weight of given liquid. The established governing equations for the static problem contain both differential operation and integral operation and the power series method plays an irreplaceable role in solving the differential-integral equations. Finally, the closed-form solutions for stress and deflection are presented and are confirmed to be convergent by the numerical examples conducted.

Published

2021

16. Closed-Form Solution for Circular Membranes under In-Plane Radial Stretching or Compressing and Out-of-Plane Gas Pressure Loading

Author

Bin-Bin Shi, Jun-Yi Sun, Ting-Kai Huang, and Xiao-Ting He

Subjects

circular membrane, initial stress, gas pressure loading, large deflection, closed-form solution, Mathematics, QA1-939

Abstract

The large deflection phenomenon of an initially flat circular membrane under out-of-plane gas pressure loading is usually involved in many technical applications, such as the pressure blister or bulge tests, where a uniform in-plane stress is often present in the initially flat circular membrane before deflection. However, there is still a lack of an effective closed-form solution for the large deflection problem with initial uniform in-plane stress. In this study, the problem is formulated and is solved analytically. The initial uniform in-plane stress is first modelled by stretching or compressing an initially flat, stress-free circular membrane radially in the plane in which the initially flat circular membrane is located, and based on this, the boundary conditions, under which the large deflection problem of an initially flat circular membrane under in-plane radial stretching or compressing and out-of-plane gas pressure loading can be solved, are determined. Therefore, the closed-form solution presented in this paper can be applied to the case where the initially flat circular membrane may, or may not, have a uniform in-plane stress before deflection, and the in-plane stress can be either tensile or compressive. The numerical example conducted shows that the closed-form solution presented has satisfactory convergence.

Published

2021

17. Large Deflection Analysis of Axially Symmetric Deformation of Prestressed Circular Membranes under Uniform Lateral Loads

Author

Xue Li, Jun-Yi Sun, Zhi-Hang Zhao, and Xiao-Ting He

Subjects

initial stress, circular membrane, large deflection, power-series method, closed-form solution, Mathematics, QA1-939

Abstract

In this study, the problem of axisymmetric deformation of peripherally fixed and uniformly laterally loaded circular membranes with arbitrary initial stress is solved analytically. This problem could be called the generalized Föppl–Hencky membrane problem as the case where the initial stress in the membrane is equal to zero is the well-known Föppl–Hencky membrane problem. The problem can be mathematically modeled only in terms of radial coordinate owing to its axial symmetry, and in the present work, it is reformulated by considering an arbitrary initial stress (tensile, compressive, or zero) and by simultaneously improving the out-of-plane equilibrium equation and geometric equation, while the formulation was previously considered to fail to improve the geometric equation. The power-series method is used to solve the reformulated boundary value problem, and a new and more refined analytic solution of the problem is presented. This solution is actually observed to be able to regress into the well-known Hencky solution of zero initial stress, allowing the considered initial stress to be zero. Moreover, the numerical example conducted shows that the obtained power-series solutions for stress and deflection converge very well, and have higher computational accuracy in comparison with the existing solutions.

Published

2020

18. A Closed-Form Solution for the Boundary Value Problem of Gas Pressurized Circular Membranes in Contact with Frictionless Rigid Plates

Author

Dong Mei, Jun-Yi Sun, Zhi-Hang Zhao, and Xiao-Ting He

Subjects

circular membrane, gas pressure loading, deflection restriction, boundary value problem, closed-form solution, Mathematics, QA1-939

Abstract

In this paper, the static problem of equilibrium of contact between an axisymmetric deflected circular membrane and a frictionless rigid plate was analytically solved, where an initially flat circular membrane is fixed on its periphery and pressurized on one side by gas such that it comes into contact with a frictionless rigid plate, resulting in a restriction on the maximum deflection of the deflected circular membrane. The power series method was employed to solve the boundary value problem of the resulting nonlinear differential equation, and a closed-form solution of the problem addressed here was presented. The difference between the axisymmetric deformation caused by gas pressure loading and that caused by gravity loading was investigated. In order to compare the presented solution applying to gas pressure loading with the existing solution applying to gravity loading, a numerical example was conducted. The result of the conducted numerical example shows that the two solutions agree basically closely for membranes lightly loaded and diverge as the external loads intensify.

Published

2020

19. A New Solution to Well-Known Hencky Problem: Improvement of In-Plane Equilibrium Equation

Author

Xue Li, Jun-Yi Sun, Zhi-Hang Zhao, Shou-Zhen Li, and Xiao-Ting He

Subjects

circular membrane, axisymmetric deformation, large deflection, equilibrium equation, power series method, Mathematics, QA1-939

Abstract

In this paper, the well-known Hencky problem—that is, the problem of axisymmetric deformation of a peripherally fixed and initially flat circular membrane subjected to transverse uniformly distributed loads—is re-solved by simultaneously considering the improvement of the out-of-plane and in-plane equilibrium equations. In which, the so-called small rotation angle assumption of the membrane is given up when establishing the out-of-plane equilibrium equation, and the in-plane equilibrium equation is, for the first time, improved by considering the effect of the deflection on the equilibrium between the radial and circumferential stress. Furthermore, the resulting nonlinear differential equation is successfully solved by using the power series method, and a new closed-form solution of the problem is finally presented. The conducted numerical example indicates that the closed-form solution presented here has a higher computational accuracy in comparison with the existing solutions of the well-known Hencky problem, especially when the deflection of the membrane is relatively large.

Published

2020

20. A Revisit of the Boundary Value Problem for Föppl–Hencky Membranes: Improvement of Geometric Equations

Author

Yong-Sheng Lian, Jun-Yi Sun, Zhi-Hang Zhao, Xiao-Ting He, and Zhou-Lian Zheng

Subjects

Föppl–Hencky membrane, boundary value problem, power series method, closed-form solution, geometric equation, Mathematics, QA1-939

Abstract

In this paper, the well-known Föppl–Hencky membrane problem—that is, the problem of axisymmetric deformation of a transversely uniformly loaded and peripherally fixed circular membrane—was resolved, and a more refined closed-form solution of the problem was presented, where the so-called small rotation angle assumption of the membrane was given up. In particular, a more effective geometric equation was, for the first time, established to replace the classic one, and finally the resulting new boundary value problem due to the improvement of geometric equation was successfully solved by the power series method. The conducted numerical example indicates that the closed-form solution presented in this study has higher computational accuracy in comparison with the existing solutions of the well-known Föppl–Hencky membrane problem. In addition, some important issues were discussed, such as the difference between membrane problems and thin plate problems, reasonable approximation or assumption during establishing geometric equations, and the contribution of reducing approximations or relaxing assumptions to the improvement of the computational accuracy and applicability of a solution. Finally, some opinions on the follow-up work for the well-known Föppl–Hencky membrane were presented.

Published

2020

21. A Closed-Form Solution of Prestressed Annular Membrane Internally-Connected with Rigid Circular Plate and Transversely-Loaded by Central Shaft

Author

Zhi-Xin Yang, Jun-Yi Sun, Zhi-Hang Zhao, Shou-Zhen Li, and Xiao-Ting He

Subjects

annular membrane, prestress, initial stress, differential equation, closed-form solution, Mathematics, QA1-939

Abstract

In this paper, we analytically dealt with the usually so-called prestressed annular membrane problem, that is, the problem of axisymmetric deformation of the annular membrane with an initial in-plane tensile stress, in which the prestressed annular membrane is peripherally fixed, internally connected with a rigid circular plate, and loaded by a shaft at the center of this rigid circular plate. The prestress effect, that is, the influence of the initial stress in the undeformed membrane on the axisymmetric deformation of the membrane, was taken into account in this study by establishing the boundary condition with initial stress, while in the existing work by establishing the physical equation with initial stress. By creating an integral expression of elementary function, the governing equation of a second-order differential equation was reduced to a first-order differential equation with an undetermined integral constant. According to the three preconditions that the undetermined integral constant is less than, equal to, or greater than zero, the resulting first-order differential equation was further divided into three cases to solve, such that each case can be solved by creating a new integral expression of elementary function. Finally, a characteristic equation for determining the three preconditions was deduced in order to make the three preconditions correspond to the situation in practice. The solution presented here could be called the extended annular membrane solution since it can be regressed into the classic annular membrane solution when the initial stress is equal to zero.

Published

2020

22. Application of Multi-Parameter Perturbation Method to Functionally-Graded, Thin, Circular Piezoelectric Plates

Author

Xiao-Ting He, Zhi-Xin Yang, Yang-Hui Li, Xue Li, and Jun-Yi Sun

Subjects

functionally-graded piezoelectric materials, thin circular plates, multi-parameter perturbation, piezoelectric coefficients, deformation, Mathematics, QA1-939

Abstract

In this study, a multi-parameter perturbation method is used for the solution of a functionally-graded, thin, circular piezoelectric plate. First, by assuming that elastic, piezoelectric, and dielectric coefficients of the functionally-graded materials vary in the form of the same exponential function, the basic equation expressed in terms of two stress functions and one electrical potential function are established in cylindrical coordinate system. Three piezoelectric coefficients are selected as perturbation parameters, and the established equations are solved by the multi-parameter perturbation method, thus obtaining up to first-order perturbation solutions. The validity of the perturbation solution obtained is verified by numerical simulations, based on layer-wise theory. The perturbation process indicates that adopting three piezoelectric coefficients as perturbation parameters follows the basic idea of perturbation theory—i.e., if the piezoelectricity may be regarded as a kind of introduced disturbance, the zero-order solution of the disturbance system corresponds exactly to the solution of functionally-graded plates without piezoelectricity. The result also indicates that the deformation magnitude of piezoelectric plates is smaller than that of plates without piezoelectricity, due to the well-known piezoelectric stiffening effect.

Published

2020

23. A Closed-Form Solution without Small-Rotation-Angle Assumption for Circular Membranes under Gas Pressure Loading

Author

Bin-Bin Shi, Xiao-Ting He, Xue Li, and Jun-Yi Sun

Subjects

Power series, Materials science, General Mathematics, closed-form solution, Mechanics, Substrate (electronics), Rotation, large deflection, Membrane, Convergence (routing), Computer Science (miscellaneous), circular membrane, QA1-939, Boundary value problem, Closed-form expression, Thin film, gas pressure loading, power series method, Engineering (miscellaneous), Mathematics

Abstract

The closed-form solution of circular membranes subjected to gas pressure loading plays an extremely important role in technical applications such as characterization of mechanical properties for freestanding thin films or thin-film/substrate systems based on pressured bulge or blister tests. However, the only two relevant closed-form solutions available in the literature are suitable only for the case where the rotation angle of membrane is relatively small, because they are derived with the small-rotation-angle assumption of membrane, that is, the rotation angle θ of membrane is assumed to be small so that “sinθ = 1/(1 + 1/tan2θ)1/2” can be approximated by “sinθ = tanθ”. Therefore, the two closed-form solutions with small-rotation-angle assumption cannot meet the requirements of these technical applications. Such a bottleneck to these technical applications is solved in this study, and a new and more refined closed-form solution without small-rotation-angle assumption is given in power series form, which is derived with “sinθ = 1/(1 + 1/tan2θ)1/2”, rather than “sinθ = tanθ”, thus being suitable for the case where the rotation angle of membrane is relatively large. This closed-form solution without small-rotation-angle assumption can naturally satisfy the remaining unused boundary condition, and numerically shows satisfactory convergence, agrees well with the closed-form solution with small-rotation-angle assumption for lightly loaded membranes with small rotation angles, and diverges distinctly for heavily loaded membranes with large rotation angles. The confirmatory experiment conducted shows that the closed-form solution without small-rotation-angle assumption is reliable and has a satisfactory calculation accuracy in comparison with the closed-form solution with small-rotation-angle assumption, particularly for heavily loaded membranes with large rotation angles.

Published

2021

24. Large Deformation Problem of Bimodular Functionally-Graded Thin Circular Plates Subjected to Transversely Uniformly-Distributed Load: Perturbation Solution without Small-Rotation-Angle Assumption

Author

Xiao-Ting He, Jun-Yi Sun, Jie-Chuan Ai, and Xue Li

Subjects

Physics, Tension (physics), General Mathematics, bimodular functionally graded materials, perturbation method, Mathematical analysis, Perturbation (astronomy), Compression (physics), Rotation, Moduli, Exponential function, Stress (mechanics), Deflection (engineering), Computer Science (miscellaneous), QA1-939, small-rotation-angle assumption, Engineering (miscellaneous), large deformation, thin circular plate, Mathematics

Abstract

In this study, the large deformation problem of a functionally-graded thin circular plate subjected to transversely uniformly-distributed load and with different moduli in tension and compression (bimodular property) is theoretically analyzed, in which the small-rotation-angle assumption, commonly used in the classical Föppl–von Kármán equations of large deflection problems, is abandoned. First, based on the mechanical model on the neutral layer, the bimodular functionally-graded property of materials is modeled as two different exponential functions in the tensile and compressive zones. Thus, the governing equations of the large deformation problem are established and improved, in which the equation of equilibrium is derived without the common small-rotation-angle assumption. Taking the central deflection as a perturbation parameter, the perturbation method is used to solve the governing equations, thus the perturbation solutions of deflection and stress are obtained under different boundary constraints and the regression of the solution is satisfied. Results indicate that the perturbation solutions presented in this study have higher computational accuracy in comparison with the existing perturbation solutions with small-rotation-angle assumption. Specially, the computational accuracies of external load and yield stress are improved by 17.22% and 28.79% at most, respectively, by the numerical examples. In addition, the small-rotation-angle assumption has a great influence on the yield stress at the center of the bimodular functionally-graded circular plate.

Published

2021

25. Closed-Form Solution for Circular Membranes under In-Plane Radial Stretching or Compressing and Out-of-Plane Gas Pressure Loading

Author

Jun-Yi Sun, Bin-Bin Shi, Xiao-Ting He, and Ting-Kai Huang

Subjects

Materials science, Plane (geometry), initial stress, General Mathematics, closed-form solution, 02 engineering and technology, Mechanics, 021001 nanoscience & nanotechnology, Stress (mechanics), large deflection, 020303 mechanical engineering & transports, Membrane, 0203 mechanical engineering, Gas pressure, Deflection (engineering), Ultimate tensile strength, Computer Science (miscellaneous), circular membrane, QA1-939, Boundary value problem, Closed-form expression, 0210 nano-technology, gas pressure loading, Engineering (miscellaneous), Mathematics

Abstract

The large deflection phenomenon of an initially flat circular membrane under out-of-plane gas pressure loading is usually involved in many technical applications, such as the pressure blister or bulge tests, where a uniform in-plane stress is often present in the initially flat circular membrane before deflection. However, there is still a lack of an effective closed-form solution for the large deflection problem with initial uniform in-plane stress. In this study, the problem is formulated and is solved analytically. The initial uniform in-plane stress is first modelled by stretching or compressing an initially flat, stress-free circular membrane radially in the plane in which the initially flat circular membrane is located, and based on this, the boundary conditions, under which the large deflection problem of an initially flat circular membrane under in-plane radial stretching or compressing and out-of-plane gas pressure loading can be solved, are determined. Therefore, the closed-form solution presented in this paper can be applied to the case where the initially flat circular membrane may, or may not, have a uniform in-plane stress before deflection, and the in-plane stress can be either tensile or compressive. The numerical example conducted shows that the closed-form solution presented has satisfactory convergence.

Published

2021

26. Steady Fluid–Structure Coupling Interface of Circular Membrane under Liquid Weight Loading: Closed-Form Solution for Differential-Integral Equations

Author

Xiao-Chen Lu, Xiao-Ting He, Jun-Yi Sun, Xue Li, and Yang Zhixin

Subjects

Mechanical equilibrium, Materials science, General Mathematics, Rotational symmetry, fluid-structure interaction, closed-form solution, 02 engineering and technology, Deformation (meteorology), differential-integral equations, law.invention, Stress (mechanics), Physics::Fluid Dynamics, 0203 mechanical engineering, law, Deflection (engineering), Fluid–structure interaction, Computer Science (miscellaneous), QA1-939, power series method, Engineering (miscellaneous), Mechanics, 021001 nanoscience & nanotechnology, Integral equation, 020303 mechanical engineering & transports, Membrane, circular membrane, 0210 nano-technology, Mathematics

Abstract

In this paper, the problem of fluid–structure interaction of a circular membrane under liquid weight loading is formulated and is solved analytically. The circular membrane is initially flat and works as the bottom of a cylindrical cup or bucket. The initially flat circular membrane will undergo axisymmetric deformation and deflection after a certain amount of liquid is poured into the cylindrical cup. The amount of the liquid poured determines the deformation and deflection of the circular membrane, while in turn, the deformation and deflection of the circular membrane changes the shape and distribution of the liquid poured on the deformed and deflected circular membrane, resulting in the so-called fluid-structure interaction between liquid and membrane. For a given amount of liquid, the fluid-structure interaction will eventually reach a static equilibrium and the fluid-structure coupling interface is steady, resulting in a static problem of axisymmetric deformation and deflection of the circular membrane under the weight of given liquid. The established governing equations for the static problem contain both differential operation and integral operation and the power series method plays an irreplaceable role in solving the differential-integral equations. Finally, the closed-form solutions for stress and deflection are presented and are confirmed to be convergent by the numerical examples conducted.

Published

2021

27. A Revisit of the Boundary Value Problem for Föppl–Hencky Membranes: Improvement of Geometric Equations

Author

Lian Yongsheng, Zhao Zhihang, Xiao-Ting He, Jun-Yi Sun, and Zheng Zhoulian

Subjects

Power series, Work (thermodynamics), General Mathematics, lcsh:Mathematics, Mathematical analysis, Rotational symmetry, Föppl–Hencky membrane, closed-form solution, 02 engineering and technology, Deformation (meteorology), 021001 nanoscience & nanotechnology, lcsh:QA1-939, geometric equation, 020303 mechanical engineering & transports, Membrane, 0203 mechanical engineering, boundary value problem, Computer Science (miscellaneous), Boundary value problem, Closed-form expression, 0210 nano-technology, power series method, Engineering (miscellaneous), Rotation (mathematics), Mathematics

Abstract

In this paper, the well-known F&ouml, ppl&ndash, Hencky membrane problem&mdash, that is, the problem of axisymmetric deformation of a transversely uniformly loaded and peripherally fixed circular membrane&mdash, was resolved, and a more refined closed-form solution of the problem was presented, where the so-called small rotation angle assumption of the membrane was given up. In particular, a more effective geometric equation was, for the first time, established to replace the classic one, and finally the resulting new boundary value problem due to the improvement of geometric equation was successfully solved by the power series method. The conducted numerical example indicates that the closed-form solution presented in this study has higher computational accuracy in comparison with the existing solutions of the well-known F&ouml, Hencky membrane problem. In addition, some important issues were discussed, such as the difference between membrane problems and thin plate problems, reasonable approximation or assumption during establishing geometric equations, and the contribution of reducing approximations or relaxing assumptions to the improvement of the computational accuracy and applicability of a solution. Finally, some opinions on the follow-up work for the well-known F&ouml, Hencky membrane were presented.

Published

2020

28. Axisymmetric Large Deflection Elastic Analysis of Hollow Annular Membranes under Transverse Uniform Loading

Author

Xue Li, Jun-Yi Sun, Xiao-Ting He, and Qi Zhang

Subjects

Power series, Materials science, Physics and Astronomy (miscellaneous), General Mathematics, Rotational symmetry, closed-form solution, Mechanics, Edge (geometry), Concentric, annular membrane, uniform transverse loading, structural analysis, large deflection, power series method, Transverse plane, Membrane, Chemistry (miscellaneous), QA1-939, Computer Science (miscellaneous), Closed-form expression, Reduction (mathematics), Mathematics

Abstract

The anticipated use of a hollow linearly elastic annular membrane for designing elastic shells has provided an impetus for this paper to investigate the large deflection geometrically nonlinear phenomena of such a hollow linearly elastic annular membrane under transverse uniform loads. The so-called hollow annular membranes differ from the traditional annular membranes available in the literature only in that the former has the inner edge attached to a movable but weightless rigid concentric circular ring while the latter has the inner edge attached to a movable but weightless rigid concentric circular plate. The hollow annular membranes remove the transverse uniform loads distributed on “circular plate” due to the use of “circular ring” and result in a reduction in elastic response. In this paper, the large deflection geometrically nonlinear problem of an initially flat, peripherally fixed, linearly elastic, transversely uniformly loaded hollow annular membrane is formulated, the problem formulated is solved by using power series method, and its closed-form solution is presented for the first time. The convergence and effectiveness of the closed-form solution presented are investigated numerically. A comparison between closed-form solutions for hollow and traditional annular membranes under the same conditions is conducted, to reveal the difference in elastic response, as well as the influence of different closed-form solutions on the anticipated use for designing elastic shells.

Published

2021

29. A Two-Dimensional Thermoelasticity Solution for Bimodular Material Beams under the Combination Action of Thermal and Mechanical Loads

Author

Hao Chang, Xiao-Ting He, Si-Rui Wen, and Jun-Yi Sun

Subjects

Body force, Materials science, Tension (physics), General Mathematics, 02 engineering and technology, Bending, Mechanics, Elasticity (physics), 021001 nanoscience & nanotechnology, Displacement (vector), tension and compression, thermoelasticity, thermal load, 020303 mechanical engineering & transports, 0203 mechanical engineering, QA1-939, Computer Science (miscellaneous), neutral layer, Boundary value problem, 0210 nano-technology, Material properties, Engineering (miscellaneous), Mathematics, Beam (structure), bimodular material beams

Abstract

A typical characteristic of bimodular material beams is that when bending, the neutral layer of the beam does not coincide with its geometric middle surface since the mechanical properties of materials in tension and compression are different. In the classical theory of elasticity, however, this characteristic has not been considered. In this study, a bimodular simply-supported beam under the combination action of thermal and mechanical loads is theoretically analyzed. First, a simplified mechanical model concerning the neutral layer is established. Based on this mechanical model, Duhamel’s theorem is used to transform the thermoelastical problem into a pure elasticity problem with imaginary body force and surface force. In solving the governing equation expressed in terms of displacement, a special solution of the displacement equation is found first, and then by utilizing the stress function method based on subarea in tension and compression, a supplement solution for the displacement governing equation without the thermal effect is derived. Lastly, the special solution and supplement solution are superimposed to satisfy boundary conditions, thus obtaining a two-dimensional thermoelasticity solution. In addition, the bimodular effect and temperature effect on the thermoelasticity solution are illustrated by computational examples.

Published

2021

30. A biparametric perturbation method for the Föppl–von Kármán equations of bimodular thin plates

Author

Jun-Yi Sun, Liang Cao, Xiao-Ting He, Zhou-Lian Zheng, and Wang Yingzhu

Subjects

Power series, Applied Mathematics, Perturbation (astronomy), 02 engineering and technology, 021001 nanoscience & nanotechnology, Nonlinear system, 020303 mechanical engineering & transports, Mathematical equations, Classical mechanics, 0203 mechanical engineering, Deflection (engineering), Von karman equations, Applied mathematics, 0210 nano-technology, Perturbation method, Analysis, Mathematics

Abstract

In this study, a biparametric perturbation method is proposed to solve the Foppl–von Karman equations of bimodular thin plates subjected to a single load. First, by using two small parameters, one describes the bimodular effect and another stands for the central deflection, we expanded the unknown deflection and stress in double power series with respect to the two parameters and obtained the approximate analytical solutions under various edge conditions. Due to the diversity of selection of parameters and its combination, by using the bimodular parameter and the load as two perturbation parameters, we elucidated further the application of this method. The use of two sets of parameter schemes both can obtain satisfactory perturbation solutions; the numerical simulations also verify this idea. The results indicate that in a biparametric perturbation method, the selection and its combination of parameters may reflect the combined effects introduced by nonlinear factors. The method proposed in this study may be used for solving other mathematical equations established in some application problems.

Published

2017

31. Application of perturbation idea to well-known Hencky problem: A perturbation solution without small-rotation-angle assumption

Author

Jun-Yi Sun, Xiao-Ting He, Lian Yongsheng, Guang-hui Liu, and Zhou-Lian Zheng

Subjects

Power series, Singular perturbation, Differential equation, Mechanical Engineering, Mathematical analysis, Rotational symmetry, Perturbation (astronomy), 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Poincaré–Lindstedt method, symbols.namesake, 020303 mechanical engineering & transports, 0203 mechanical engineering, Mechanics of Materials, symbols, General Materials Science, Boundary value problem, Large deflection, 0210 nano-technology, Civil and Structural Engineering, Mathematics

Abstract

In existing studies, the well-known Hencky problem, i.e. the large deflection problem of axisymmetric deformation of a circular membrane subjected to uniformly distributed loads, has been analyzed generally on small-rotation-angle assumption and solved by using the common power series method. In fact, the problem studied and the method adopted may be effectively expanded to meet the needs of larger deformation. In this study, the classical Hencky problem was extended to the problem without small-rotation-angle assumption and resolved by using the perturbation idea combining with power series method. First, the governing differential equations used for the solution of stress and deflection in the perturbed system were established. Taking the load as a perturbation parameter, the stress and deflection were expanded with respect to the parameter. By substituting the expansions into the governing equations and corresponding boundary conditions, the perturbation solution of all levels were obtained, in which the zero-order perturbation solution exactly corresponds to the small-rotation-angle solution, i.e. the solution of the unperturbed system. The results indicate that if the perturbed and unperturbed systems as well as the corresponding differential equations may be distinguished, the perturbation method proposed in this study can be extended to solve other nonlinear differential equations, as long as the differential equation of unperturbed system may be obtained by letting a certain parameter be zero in the corresponding equation of perturbed system.

Published

2017

32. An elasticity solution of functionally graded beams with different moduli in tension and compression

Author

Wei-min Li, Zhi-Xiang Wang, Jun-Yi Sun, and Xiao-Ting He

Subjects

Mechanical Engineering, General Mathematics, 02 engineering and technology, Elasticity (physics), 021001 nanoscience & nanotechnology, Moduli, 020303 mechanical engineering & transports, 0203 mechanical engineering, Mechanics of Materials, General Materials Science, Composite material, 0210 nano-technology, Beam (structure), Civil and Structural Engineering, Mathematics

Abstract

In this study, we analytically solved the problem of a functionally graded beam with different moduli in tension and compression under the action of uniformly distributed loads. By determin...

Published

2016

33. Closed-form solution of well-known Hencky problem without small-rotation-angle assumption

Author

Lian Yongsheng, Yang Zhixin, Jun-Yi Sun, Zhou-Lian Zheng, and Xiao-Ting He

Subjects

Deformation (mechanics), Differential equation, Applied Mathematics, Mathematical analysis, Computational Mechanics, Rotational symmetry, 02 engineering and technology, 021001 nanoscience & nanotechnology, Transverse plane, 020303 mechanical engineering & transports, Classical mechanics, 0203 mechanical engineering, Large deflection, Closed-form expression, 0210 nano-technology, Constant (mathematics), Rotation (mathematics), Mathematics

Abstract

In this paper, the well-known Hencky problem, the large deflection problem of axisymmetric deformation of uniformly loaded circular membranes, was resolved, where the small-rotation-angle assumption usually adopted in membrane problems was given up. The presented closed-form solution has a higher accuracy than well-known Hencky solution, a better understanding of the non-linear behavior of the considered problem could thus be reached. The presented numerical example shows that, the important integral constant controlling differential equations should change along with the increase of the applied transverse loads, but in well-known Hencky solution it becomes a constant due to the adopted small-rotation-angle assumption, resulting in the calculation error to increase, especially when the applied transverse loads is relatively large the well-known Hencky solution will no longer apply.

Published

2016

34. A New Solution to Well-Known Hencky Problem: Improvement of In-Plane Equilibrium Equation

Author

Zhao Zhihang, Jun-Yi Sun, Xiao-Ting He, Xue Li, and Shou-Zhen Li

Subjects

Power series, lcsh:Mathematics, General Mathematics, Mathematical analysis, Rotational symmetry, 02 engineering and technology, Equilibrium equation, lcsh:QA1-939, 021001 nanoscience & nanotechnology, equilibrium equation, Nonlinear differential equations, large deflection, Transverse plane, In plane, 020303 mechanical engineering & transports, 0203 mechanical engineering, Deflection (engineering), circular membrane, Computer Science (miscellaneous), axisymmetric deformation, Cylinder stress, power series method, 0210 nano-technology, Engineering (miscellaneous), Mathematics

Abstract

In this paper, the well-known Hencky problem&mdash, that is, the problem of axisymmetric deformation of a peripherally fixed and initially flat circular membrane subjected to transverse uniformly distributed loads&mdash, is re-solved by simultaneously considering the improvement of the out-of-plane and in-plane equilibrium equations. In which, the so-called small rotation angle assumption of the membrane is given up when establishing the out-of-plane equilibrium equation, and the in-plane equilibrium equation is, for the first time, improved by considering the effect of the deflection on the equilibrium between the radial and circumferential stress. Furthermore, the resulting nonlinear differential equation is successfully solved by using the power series method, and a new closed-form solution of the problem is finally presented. The conducted numerical example indicates that the closed-form solution presented here has a higher computational accuracy in comparison with the existing solutions of the well-known Hencky problem, especially when the deflection of the membrane is relatively large.

Published

2020

35. Application of a biparametric perturbation method to large-deflection circular plate problems with a bimodular effect under combined loads

Author

Jun-Yi Sun, Xiao-Ting He, Zhou-Lian Zheng, and Liang Cao

Subjects

Power series, Computer simulation, Applied Mathematics, Mathematical analysis, Stiffness, Young's modulus, Superposition theorem, Nonlinear system, symbols.namesake, Classical mechanics, Deflection (engineering), symbols, medicine, Bearing capacity, medicine.symptom, Analysis, Mathematics

Abstract

The large deflection condition of a bimodular plate may yield a dual nonlinear problem where the superposition theorem is inapplicable. In this study, the bimodular Foppl–von Karman equations of a plate subjected to the combined action of a uniformly distributed load and a centrally concentrated force are solved using a biparametric perturbation method. First, the deflection and radial membrane stress were expanded in double power series with respect to the two types of loads. However, the biparametric perturbation solution obtained exhibited a relatively slow rate of convergence. Next, by introducing a generalized load and its corresponding generalized displacement, the solution is expanded in a single power series with respect to the generalized displacement parameter, thereby leading to the better convergence on the solution. A numerical simulation is also used to verify the correctness of the biparametric perturbation solution. The introduction of a bimodular effect will modify the stiffness of the plate to some extent. In particular, the bearing capacity of the plate will be strengthened further when the compressive modulus is greater than the tensile modulus.

Published

2014

36. General perturbation solution of large-deflection circular plate with different moduli in tension and compression under various edge conditions

Author

Jun-Yi Sun, Xiao-Ting He, Zhou-Lian Zheng, Zhi-Xiang Wang, and Qiang Chen

Subjects

Large deformation, Applied Mathematics, Mechanical Engineering, Mathematical analysis, Perturbation (astronomy), Modulus, Slip (materials science), Moduli, Classical mechanics, Mechanics of Materials, Large deflection, Boundary value problem, Material properties, Mathematics

Abstract

The large deflection problem for a thin circular plate with different moduli in tension and compression has dually non-linear characteristics. In this paper, we use perturbation technique to obtain a general analytical solution of thin circular plate with different moduli in tension and compression, in which four edge conditions including rigidly clamped, clamped but free to slip, simply hinged and simply supported are considered. Because the perturbation solution is expanded in ascending powers of a known perturbation parameter (central deflection, for example) and the unknown constants and functions in the solution are gradually determined by decomposing boundary conditions and governing equation, the constants and functions obtained in such a manner have an inherent consistency concerning material properties. The results show that via construction of some parameters reflecting materials properties, not only the solution based on bimodular elasticity theory may regress to that on classical theory with singular modulus, but also the solution obtained under simply hinged edge may serve as a general solution to describe other three edge conditions. Via the general solution, the relations of load vs. central deflection, the plate–membrane transition for bimodular problem and the radial membrane stresses and bending stresses at the center and edge of the plate, are also discussed. Moreover, the comparison between the analytical solutions and numerical results indicates that the perturbation solutions based on the central deflection are overall valid. This work will be helpful for analyzing the mechanical behaviors of flexible layer structures while considering large deformation and bimodular effect.

Published

2013

37. Power series solution of circular membrane under uniformly distributed loads: investigation into Hencky transformation

Author

Rong Yang, Zhou-Lian Zheng, Xiaowei Gao, Jun-Yi Sun, and Xiao-Ting He

Subjects

Power series, Transformation (function), Deformation (mechanics), Mechanics of Materials, Mechanical Engineering, Mathematical analysis, Rotational symmetry, Geometry, Building and Construction, Action (physics), Civil and Structural Engineering, Mathematics

Abstract

In this paper, the problem of axisymmetric deformation of the circular membrane fixed at its perimeter under the action of uniformly-distributed loads was resolved by exactly using power series method, and the solution of the problem was presented. An investigation into the so-called Hencky transformation was carried out, based on the solution presented here. The results obtained here indicate that the well-known Hencky solution is, without doubt, correct, but in the published papers the statement about its derivation is incorrect, and the so-called Hencky transformation is invalid and hence may not be extended to use as a general mathematical method.

Published

2013

38. Nonlinear large deflection problems of beams with gradient: A biparametric perturbation method

Author

Zheng-Ying Li, Jun-Yi Sun, Xiao-Ting He, Xing-Jian Hu, and Liang Cao

Subjects

Computational Mathematics, Nonlinear system, Cantilever, Classical mechanics, Deflection (engineering), Applied Mathematics, Mathematical analysis, Large deflection, Boundary value problem, Perturbation method, Arc length, Beam (structure), Mathematics

Abstract

For beams with gradient, due to the combined influences introduced by loads and gradient, the first derivative item in Euler-Bernoulli equation can not be neglected thus making the solution of the problem be a nonlinear large deflection one. In this paper, we use a new perturbation method with two small parameters, one describes the loads effect and another describes the geometrical nature of the problem, to solve the nonlinear large deflection problem of beams with gradient under the two different boundary conditions. We derive the first and second order approximate analytical solution of the deflection, the rotation and the arc length of the beam, as well as the internal forces of the beam at the end. The results indicate that the choice of two independent parameters may describe comprehensively the nonlinear effects caused by loads and gradient, which enables the approximate solution to be precise enough to be used for the analysis of large-deflection beam with gradient.

Published

2013

39. Applying the equivalent section method to solve beam subjected to lateral force and bending-compression column with different moduli

Author

Shan-lin Chen, Jun-Yi Sun, and Xiao-Ting He

Subjects

Mechanical Engineering, Mathematical analysis, Geometry, Bending, Condensed Matter Physics, Compression (physics), Displacement (vector), Moduli, Mathematics::Algebraic Geometry, Mechanics of Materials, Shear stress, General Materials Science, Elasticity (economics), Beam (structure), Civil and Structural Engineering, Neutral axis, Mathematics

Abstract

Based on elastic theory of different tension-compression moduli, bending beam subjected to lateral force and bending-compression column with different moduli were solved by the equivalent section method. Formulas for the neutral axis, normal stress, shear stress and displacement were developed also. This equivalent section method can turn conveniently different moduli problems into the similar moduli ones, i.e., classical elasticity problems so the existent results aimed beams and columns with similar moduli both can be used indiscriminately without complicated derived process. Compared with the present derived method based on different moduli theory the applicability and efficiency of equivalent section method is demonstrated.

Published

2007

40. Nonlinear Free Vibration Analysis of Axisymmetric Polar Orthotropic Circular Membranes under the Fixed Boundary Condition

Author

Zhou-Lian Zheng, Jianjun Guo, Chuan-Xi Xie, Weiju Song, Fa-Ming Lu, Jun-Yi Sun, and Xiao-Ting He

Subjects

Article Subject, General Mathematics, lcsh:Mathematics, Mathematical analysis, General Engineering, Orthotropic material, lcsh:QA1-939, Vibration, symbols.namesake, Nonlinear system, Classical mechanics, Deflection (engineering), lcsh:TA1-2040, symbols, Virtual displacement, Boundary value problem, Galerkin method, lcsh:Engineering (General). Civil engineering (General), Bessel function, Mathematics

Abstract

This paper presents the nonlinear free vibration analysis of axisymmetric polar orthotropic circular membrane, based on the large deflection theory of membrane and the principle of virtual displacement. We have derived the governing equations of nonlinear free vibration of circular membrane and solved them by the Galerkin method and the Bessel function to obtain the generally exact formula of nonlinear vibration frequency of circular membrane with outer edges fixed. The formula could be degraded into the solution from small deflection vibration; thus, its correctness has been verified. Finally, the paper gives the computational examples and comparative analysis with the other solution. The frequency is enlarged with the increase of the initial displacement, and the larger the initial displacement is, the larger the effect on the frequency is, and vice versa. When the initial displacement approaches zero, the result is consistent with that obtained on the basis of the small deflection theory. Results obtained from this paper provide the accurate theory for the measurement of the pretension of polar orthotropic composite materials by frequency method and some theoretical basis for the research of the dynamic response of membrane structure.

Published

2014

41. Convergence analysis of a finite element method based on different moduli in tension and compression

Author

Ying-min Li, Shan-lin Chen, Jun-Yi Sun, Xiao-Ting He, and Zhou-Lian Zheng

Subjects

Mathematical optimization, Computation, Mechanical Engineering, Applied Mathematics, Constitutive equation, hp-FEM, Constitutive model, Compression (physics), Condensed Matter Physics, Finite element method, Local convergence, Materials Science(all), Finite element, Mechanics of Materials, Shear modulus, Modeling and Simulation, Modelling and Simulation, Convergence (routing), Applied mathematics, General Materials Science, Bimodulus, Convergence, Mathematics, Plane stress

Abstract

When analyzing materials that exhibit different mechanical behaviors in tension and compression, an iterative approach is required due to material nonlinearities. Because of this iterative strategy, numerical instabilities may occur in the computational procedure. In this paper, we analyze the reason why iterative computation sometimes does not converge. We also present a method to accelerate convergence. This method is the introduction of a new pattern of shear modulus that was strictly derived according to the constitutive model based on the bimodular elasticity theory presented by Ambartsumyan. We test this procedure with a numerical example concerning a plane stress problem. Results obtained from this example show that the proposed method reduces the cost of computation and accelerates the convergence of the solution.