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Simplified permeable surface correction for frequency-domain Ffowcs Williams and Hawkings integrals

Zhiteng Zhou, Hongping Wang, Shizhao Wang

Corrected proof , doi: 10.1016/j.taml.2021.100259

[Abstract] (120) [FullText HTML] (64) [PDF 2704KB] (1)

Abstract:
A simplified surface correction formulation is proposed to diminish the far-field spurious sound generated by the quadrupole source term in Ffowcs Williams and Hawkings (FW-H) integrals. The proposed formulation utilizes the far-field asymptotics of the Green's function to simplify the computation of its high-order derivatives, which circumvents the difficulties reported in the original frequency-domain surface correction formulation. The proposed formulation has been validated by investigating the benchmark case of sound generated by a convecting vortex. The results show that the proposed formulation successfully eliminates the spurious sound. The applications of the proposed formulation to flows with some special parameters are also discussed.

Electrothermal analysis of radiofrequency tissue ablation with injectable flexible electrodes considering bio-heat transfer

Min Hua, Zhixiong Fengb, Yuguang Chuc, Yuhang Lia

Accepted Manuscript

[Abstract] (22) [FullText HTML] (17) [PDF 3321KB] (0)

Abstract:
Flexible electrodes have been widely focused on in recent years due to their special mechanical properties, which can be directly integrated onto human soft tissues to actively take effects on human body or passively monitor human vital signs. These flexible electrodes provide a new routine to realize clinical treatment of accurate thermal ablation in the biological tissues via radiofrequency ablation (RFA). Meanwhile, accurately controlling of thermal field is very significant for the thermal ablation in the clinical therapeutics to prevent the healthy tissue from excessive burning. In this paper, both one-dimensional and two-dimensional axisymmetric analytical models for the electrothermal analysis of radiofrequency ablation considering bio-heat transfer are established, which are verified by finite element analysis (FEA) and in vitro experiments on pig skins. In the model, the electrical field and thermal field are both derived analytically to accurately predict the temperature rise in the biological tissues. Furthermore, parameters, such as the blood flow convection in living tissues and thickness of tissue, have obvious effects on the thermal field in the tissues. They may pave the theoretical foundation and provide guidance of RFA with flexible electrodes in the future.

Bedding plane-embedded augmented virtual internal bonds for fracture propagation simulation in shale

Zihan Liu, Zhennan Zhang, Ahmad Ghassemi

Corrected proof , doi: 10.1016/j.taml.2021.100253

[Abstract] (56) [FullText HTML] (49) [PDF 3178KB] (7)

Abstract:
To effectively simulate the fracture propagation in shale, the bedding plane (BP) effect is incorporated into the augmented virtual internal bond (AVIB) constitutive relation through BP tensor. Comparing the BP-embedded AVIB with the theory of transverse isotropy, it is found the approach can represent the anisotropic properties induced by parallel BPs. Through the simulation example, it is found that this method can simulate the stiffness anisotropy of shale and can represent the effect of BPs on hydraulic fracture propagation direction. Compared with the BP-embedded VIB, this method can account for the various Poisson's ratio. It provides a feasible approach to simulate the fracture propagation in shale.

Neuroevolution-enabled adaptation of the Jacobi method for Poisson’s equation with density discontinuities

T.-R. Xiang, X. I. A. Yang, Y.-P. Shi

Accepted Manuscript , doi: 10.1016/j.taml.2021.100252

[Abstract] (76) [FullText HTML] (49) [PDF 4093KB] (1)

Abstract:
Lacking labeled examples of working numerical strategies, adapting an iterative solver to accommodate a numerical issue, e.g., density discontinuities in the pressure Poisson equation, is non-trivial and usually involves a lot of trial and error. Here, we resort to evolutionary neural network. A evolutionary neural network observes the outcome of an action and adapts its strategy accordingly. The process requires no labeled data but only a measure of a network’s performance at a task. Applying neuro-evolution and adapting the Jacobi iterative method for the pressure Poisson equation with density discontinuities, we show that the adapted Jacobi method is able to accommodate density discontinuities.

Error of large-eddy simulation in the wall pressure fluctuation of a turbulent channel flow

Rong Li, Bowen Yang, Zixuan Yang, Shizao Wang, Guowei He

Accepted Manuscript

[Abstract] (239) [FullText HTML] (76) [PDF 2788KB] (14)

Abstract:
We analyze the error of large-eddy simulation (LES) in wall pressure fluctuation of a turbulent channel flow. To separate different sources of the error, we conduct both direct numerical simulations (DNS) and LES, and apply an explicit filter on DNS data to obtain filtered DNS (FDNS) data. The error of LES is consequently decomposed into two parts: The first part is the error of FDNS with respect to DNS, which quantifies the influence of the filter operation. The second part is the difference between LES and FDNS induced by the error of LES in velocity field. By comparing the root-mean-square value and the wavenumber-frequency spectrum of the wall pressure fluctuation, it is found that the inaccuracy of the velocity fluctuations is the dominant source that induces the error of LES in the wall pressure fluctuation. The present study provides a basis on future LES studies of the wall pressure fluctuation.

Supplyment

Accepted Manuscript

[Abstract] (120) [FullText HTML] (68) [PDF 2408KB] (0)

Abstract:
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Analytical and Numerical Studies for Seiches in a Closed Basin with Various Geometric Shape of Longitudinal Section

I. Magdalena, Nadhira karima, H. Q. Rif'atin

Accepted Manuscript

[Abstract] (207) [FullText HTML] (80) [PDF 3043KB] (2)

Abstract:
Seiches are long-period standing waves with a unique period called a natural resonant period, during which the phenomenon of resonance occurs. The occurrence of resonance in coastal areas can cause destruction to surrounding natural and man-made structures. By determining the resonant period of a given basin, we can pinpoint the conditions that allow waves to achieve resonance. In this study, a mathematical model is developed from the shallow water equations to examine seiches and resonances in various types of closed basin. The developed model is solved analytically using the separation of variables method to determine the seiches' fundamental resonant periods. Comparisons between the analytical solutions and experimental measurements for resonant periods are also provided. It is shown that the analytical resonant period confirms the experimental data for closed basin of various geometric profiles. Using a finite volume method on a staggered grid, the model is solved numerically to simulate the wave profile when resonance phenomenon occurs. Through those numerical simulations, we also obtain the fundamental resonant period for each basin which agrees with the derived analytical period.

Computing mean fields with known Reynolds stresses at steady state

Xianwen Guo, Zhenhua Xia, Shiyi Chen

Accepted Manuscript

[Abstract] (219) [FullText HTML] (72) [PDF 3354KB] (10)

Abstract:
With the rising of modern data science, data-driven turbulence modeling with the aid of machine learning algorithms is becoming a new promising field. Many approaches are able to achieve better Reynolds stress prediction, with much lower modeling error (

\begin{document}$\epsilon_{\rm{M}}$\end{document}

), than traditional RANS models, but they still suffer from numerical error and stability issues when the mean velocity fields are estimated by solving Reynolds-averaged Navier-Stokes (RANS) equations with the predicted Reynolds stresses. This fact illustrates that the error of solving the RANS equations (

\begin{document}$\epsilon_{\rm{P}}$\end{document}

) is also very important for a RANS simulation. In the present work, the error

\begin{document}$\epsilon_{\rm{P}}$\end{document}

is studied separately by using the Reynolds stresses obtained from direct numerical simulation (DNS)/highly resolved large-eddy simulation to minimize the modeling error

\begin{document}$\epsilon_{\rm{M}}$\end{document}

, and the sources of

\begin{document}$\epsilon_{\rm{P}}$\end{document}

are derived mathematically. For the implementations with known Reynolds stresses solely, we suggest to run an auxiliary RANS simulation to make a first guess on

\begin{document}$\nu_{\rm{t}}^*$\end{document}

and

\begin{document}$S_{ij}^0$\end{document}

. With around 10 iterations, the error of the streamwise velocity component could be reduced by about one-order of magnitude in flow over periodic hills. The present work is not to develop a new RANS model, but to clarify the facts that obtaining mean field with known Reynolds stresses is nontrivial and that the nonlinear part of the Reynolds stresses is very important in flow problems with separations. The proposed approach to reduce

\begin{document}$\epsilon_{\rm{P}}$\end{document}

may be very useful for the a posteriori applications of the data-driven turbulence models.

Effect of interfacial stiffness on the stretchability of metal/elastomer bilayers under in-plane biaxial tension

Zheng Jia, Teng Li

Accepted Manuscript

[Abstract] (295) [FullText HTML] (69) [PDF 2733KB] (3)

Abstract:
Flexible electronic devices are often subjected to large and repeated deformation, so that their functional components such as metal interconnects need to sustain strains up to tens of percent, which is far beyond the intrinsic deformability of metal materials (~1%). To meet the stringent requirements of flexible electronics, metal/elastomer bilayers, a stretchable structure that consists of a metal film adhered to a stretchable elastomer substrate, have been developed to improve the stretch capability of metal interconnects. Previous studies have predicted that the metal/elastomer bilayers are much more stretchable than freestanding metal films. However, these investigations usually assume perfect bonding between the metal and elastomer layers. In this work, the effect of the metal/elastomer interface with a finite interfacial stiffness on the stretchability of bilayer structures is analyzed. The results show that the assumption of perfect interface (with infinite interfacial stiffness) may lead to an overestimation of the stretchability of bilayer structures. It is also demonstrated that increased adhesion between the metal and elastomer layers can enhance the stretchability of the metal layer.

Experimental study of the effect of slotted blades on the Savonius wind turbine performance

Dominicus Danardono Dwi Prija Tjahjana, Zainal Arifin, Suyitno Suyitno, Wibawa Endra Juwana, Aditya Rio Prabowo, Catur Harsito

Accepted Manuscript

[Abstract] (219) [FullText HTML] (68) [PDF 3791KB] (6)

Abstract:
This study investigates the effect of Reynolds number on the performance of Savonius wind turbine with slotted blades. The turbine performance investigation was based on the torque coefficient (Ct), power coefficient (Cp), and tip speed ratio (TSR). The experiment used two number of blade configuration, blade overlap ratio of 10%, 12.5% and 20%, slotted position of 15%, 20%, 25% and 35%, and also slotted gap width of 3 mm, 5 mm, 7 mm, and 9 mm. The wind speed carried out in this experiment are 5.94 m/s, 6.46 m/s, 6.99 m/s, and 7.27 m/s, which are generated from the fan blowers as a wind source. The Savonius turbine with 10% overlap ratio shows the best performance. The highest Cp obtained is 0.138 by the variation of a 3 mm gap with Re of 1.44 × 10⁴ and 0.526 tip speed ratio (TSR).

Fundamental kinematics laws of interstitial fluid flows on vascular walls

Yajun Yin, Hongyi Li, Gang Peng, Xiaobin Yu, Yiya Kong

Accepted Manuscript

[Abstract] (124) [FullText HTML] (71) [PDF 2521KB] (10)

Abstract:
In the previous studies, the phenomenon that the interstitial fluid (ISF) can flow along tunica adventitia of the arteries and veins in both human and animal bodies was reported. On the basis of these studies, this paper aims to: (i) summarize the basic properties of the ISF flows in the walls of arteries and veins, (ii) combine the basic properties with axiomaticism and abstract the axiom for ISF flows, and (iii) propose three fundamental laws of the ISF flow, (i.e., the existence law, the homotropic law and the reverse law). The three laws provide solid theoretical basement for exploring the kinematic patterns of interstitial fluid flow in the cardiovascular system.

Analytical solutions for inflation of pre-stretched elastomeric circular membranes under uniform pressure

Jianghong Yuan, Xianlin Liu, Haibin Xia, Yin Huang

Accepted Manuscript

[Abstract] (210) [FullText HTML] (64) [PDF 2851KB] (11)

Abstract:
Elastomeric membranes are frequently used in several emerging fields such as soft robotics and flexible electronics. For convenience of the structural design, it is very attractive to find simple analytical solutions to well describe their elastic deformations in response to external loadings. However, both the material/geometrical nonlinearity and the deformation inhomogeneity due to boundary constraints make it much challenging to get an exact analytical solution. In this paper, we focus on the inflation of a pre-stretched elastomeric circular membrane under uniform pressure, and derive an approximate analytical solution of the pressure-volume curve based upon a reasonable assumption on the shape of the inflated membrane. Such an explicit expression enables us to quantitatively design the material and geometrical parameters of the pre-stretched membrane to generate a target pressure-volume curve with prescribed peak point and initial slope. This work would be of help in the simplified mechanical design of structures involving elastomeric membranes.

Why neural networks apply to scientific computing?

Shaoqiang Tang, Yang Yang

Accepted Manuscript

[Abstract] (127) [FullText HTML] (67) [PDF 3294KB] (3)

Abstract:
In recent years, neural networks have become an increasingly powerful tool in scientific computing. The universal approximation theorem asserts that a neural network may be constructed to approximate any given continuous function at desired accuracy. The backpropagation algorithm further allows efficient optimization of the parameters in training a neural network. Powered by GPU's, effective computations for scientific and engineering problems are thereby enabled. In addition, we show that finite element shape functions may also be approximated by neural networks.

A Geometry-based framework for modeling the complexity of origami folding

Samuel Schulman, Xin Ning

Accepted Manuscript

[Abstract] (183) [FullText HTML] (65) [PDF 2737KB] (1)

Abstract:
This paper presents a quantitative framework to analyze the complexity of folding origami structures from flat membranes. Extensive efforts have realized intricate origami patterns with desired functions such as mechanical properties, packaging efficiency, and deployment behavior. However, the complexity associated with the manufacturing or folding of origami patterns has not been explored. Understanding how difficult origami structures are to make, and how much time they require to form is crucial information to determining the practical feasibility of origami designs and future applications such as robotic origami assembly in space. In this work, we develop this origami complexity metric by modeling the geometric properties and crease formation of the origami structure, from which it outputs crease and pattern complexity values and a prediction of the time to complete the pattern assembly, based on the characteristics of the operator. The framework is experimentally validated by fabricating various Miura-ori origami paper models.

Meandering motions within the viscous sublayer: Supplementary materials

S. Santosh Kumar, Xinyi Huang, Xiang Yang, Jiarong Hong

Corrected proof

[Abstract] (230) [FullText HTML] (89) [PDF 2904KB] (3)

Abstract:
$v.abstractInfoEn

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Letter

Research on refined reconstruction method of airfoil pressure based on compressed sensing

Xuan Zhao, Lin Du, Xuhao Peng, Zichen Deng, Weiwei Zhang

2021, 11(2): 73 -80. doi: 10.1016/j.taml.2021.100223

[Abstract] (239) [FullText HTML] (97) [PDF 3134KB] (8)

Abstract:
The placement of pressure taps on the surface of the wind tunnel test model is an important means to obtain the surface pressure distribution. However, limited by space location and experimental cost, it is difficult to arrange enough pressure measuring taps on the surface of complex models to obtain complete pressure distribution information, thus it is impossible to obtain accurate lift and moment characteristics through integration. The paper proposes a refined reconstruction method of airfoil surface pressure based on compressed sensing, which can reconstruct the pressure distribution with high precision with less pressure measurement data. Tests on typical airfoil subsonic flow around flow show that the accuracy of lift and moment after the pressure integration reconstructed by 4-8 measuring points can meet the requirements of the national military standard. The algorithm is robust to noise, and provides a new idea for obtaining accurate force data from sparse surface pressure tests in engineering.

Bifurcation mechanism of interfacial electrohydrodynamic gravity-capillary waves near the minimum phase speed under a horizontal electric field

Gexing Xu, Zhi Lin

2021, 11(2): 81 -88. doi: 10.1016/j.taml.2021.100224

[Abstract] (160) [FullText HTML] (96) [PDF 2928KB] (5)

Abstract:
We investigate the evolution of interfacial gravity-capillary waves propagating along the interface between two dielectric fluids under the action of a horizontal electric field. There is a uniform background flow in each layer, and the relative motion tends to induce Kelvin-Helmholtz (KH) instability. The combined effects of gravity, surface tension and electrically induced forces are all taken into account. Under the short-wave assumption, the expansion and truncation method of Dirichlet-Neumann (DN) operators is applied to derive a reduced dynamical model. When KH instability is suppressed linearly by a considerably large electric field, our numerical results reveal that in certain regions of parameter space, nonlinear symmetric traveling wave solutions can be found near the minimum phase speed. Additionally, the detailed bifurcation structures are presented together with typical wave profiles.

Analytical solutions for sediment concentration in waves based on linear diffusivity

Yiqin Xie, Jifu Zhou, Xu Wang, Yanrong Kuai, Yongjun Lu

2021, 11(2): 89 -93. doi: 10.1016/j.taml.2021.100232

[Abstract] (235) [FullText HTML] (83) [PDF 2742KB] (2)

Abstract:
Two kinds of analytical solutions are derived through Laplace transform for the equation that governs wave-induced suspended sediment concentration with linear sediment diffusivity under two kinds of bottom boundary conditions, namely the reference concentration (Dirichlet) and pickup function (Numann), based on a variable transformation that is worked out to transform the governing equation into a modified Bessel equation. The ability of the two analytical solutions to describe the profiles of suspended sediment concentration is discussed by comparing with different experimental data. And it is demonstrated that the two analytical solutions can well describe the process of wave-induced suspended sediment concentration, including the amplitude and phase and vertical profile of sediment concentration. Furthermore, the solution with boundary condition of pickup function provides better results than that of reference concentration in terms of the phase-dependent variation of concentration.

Complexity analysis of the Portevin-Le Chatelier in an Al alloy at different temperatures

Jianfei Xu, Guoxiong Chen, Shihua Fu

2021, 11(2): 94 -98. doi: 10.1016/j.taml.2021.100233

[Abstract] (177) [FullText HTML] (93) [PDF 2610KB] (23)

Abstract:
The complexity of the Portevin-Le Chatelier (PLC) effect in an Al alloy at different temperatures was analyzed by modified multiscale entropy. The results show that three evolutions of entropy with scale factor, i.e., near zero, monotonically increasing and peak-shape, were observed corresponding to the smooth curves, type-A serrations and type-B/-C serrations, respectively. The scale factor at the peak was one-third of the average serration period. The sample entropy increased initially and then decreased with temperature, which was opposite to the critical strain. It is also suggested that the type-A serrations corresponded to self-organized criticality and the type-B/-C serrations corresponded to chaos through the evolutions of entropy with scale factor.

Design of crashworthy attenuator structures as a part of vehicle safety against impact: Application of waste aluminum can-based material

Laksmana Widi Prasetya, Aditya Rio Prabowo, Ubaidillah Ubaidillah, Iwan Istanto, Nur Azmah Binti Nordin

2021, 11(2): 99 -108. doi: 10.1016/j.taml.2021.100235

[Abstract] (258) [FullText HTML] (82) [PDF 3549KB] (6)

Abstract:
The impact attenuator is an essential system in both race cars and urban vehicles. The structure of an impact attenuator serves as a safety barrier between the impacted surface and the driver in an accident. Attenuator materials tend to have a high price; thus, alternative materials were explored in the current work, i.e., used cans from food and beverage containers. The study deployed a nonlinear finite element algorithm to calculate a series of impacts on the attenuator structures. The thickness of the cans and velocity of the impact were considered as the main parameters. Analysis results concluded that the attenuator's average energy was 16000 J for a can thickness of 1 mm. This value is more than two times the 0.5 mm thick used cans. The attenuator's new design was then matched with an attenuator regulation, and the results surpassed the standard value of 7350 J.

Derivation of FFT numerical bounds of the effective properties of composites and polycristals

Minh-Tan Nguyen, Quy-Dong To, Vincent Monchiet

2021, 11(2): 109 -118. doi: 10.1016/j.taml.2021.100236

[Abstract] (113) [FullText HTML] (94) [PDF 3027KB] (2)

Abstract:
In this paper, we provide exact fast Fourier transform (FFT)-based numerical bounds for the elastic properties of composites having arbitrary microstructures. Two bounds, an upper and a lower, are derived by considering usual variational principles based on the strain and the stress potentials. The bounds are computed by solving the Lippmann-Schwinger equation together with the shape coefficients which allow an exact description of the microstructure of the composite. These coefficients are the exact Fourier transform of the characteristic functions of the phases. In this study, the geometry of the microstructure is approximated by polygonals (two-dimensional (2D) objects) and by polyhedrons (three-dimensional (3D) objects) for which exact expressions of the shape coefficients are available. Various applications are presented in the paper showing the relevance of the approach. In the first benchmark example, we consider the case of a composite with fibers. The effective elastic coefficients ares derived and compared, considering the exact shape coefficient of the circular inclusion and its approximation with a polygonal. Next, the homogenized elastic coefficients are derived for a composite reinforced by 2D flower-shaped inclusions and with 3D toroidal-shaped inclusions. Finally, the method is applied to polycristals considering Voronoi tessellations for which the description with polygonals and polyhedrons becomes exact. The comparison with the original FFT method of Moulinec and Suquet is provided in order to show the relevance of these numerical bounds.

A model for universal spatial variations of temperature fluctuations in turbulent Rayleigh-Bénard convection

Xiaozhou He, Eberhard Bodenschatz, Guenter Ahlers

2021, 11(2): 119 -122. doi: 10.1016/j.taml.2021.100237

[Abstract] (236) [FullText HTML] (90) [PDF 2469KB] (7)

Abstract:
We propose a theoretical model for spatial variations of the temperature variance

\begin{document}$\sigma^2(z,r)$\end{document}

(z is the distance from the sample bottom and r the radial coordinate) in turbulent Rayleigh-Bénard convection (RBC). Adapting the “attached-eddy” model of shear flow to the plumes of RBC, we derived an equation for

\begin{document}$\sigma^2$\end{document}

which is based on the universal scaling of the normalized RBC temperature spectra. This equation includes both logarithmic and power-law dependences on

\begin{document}$z/\lambda_{th}$\end{document}

, where

\begin{document}$\lambda_{th}$\end{document}

is the thermal boundary layer thickness. The equation parameters depend on r and the Prandtl number Pr, but have only an extremely weak dependence on the Rayleigh number Ra Thus our model provides a near-universal equation for the temperature variance profile in turbulent RBC.

Meandering motions within the viscous sublayer

S. Santosh Kumar, Xinyi Huang, Xiang Yang, Jiarong Hong

2021, 11(2): 123 -127. doi: 10.1016/j.taml.2021.100239

[Abstract] (316) [FullText HTML] (91) [PDF 4109KB] (1)

Abstract:
Impact of viscous sublayer scale roughness elements on large scale flows have not been fully understood and require high resolution 3D flow measurements to unravel. However, existing approaches fail to provide sufficient resolution for such measurements to fully resolve the sublayer. In this study, we use digital Fresnel reflection holography to capture 3D flows within the viscous sublayer at sub-viscous resolutions. The measurement highlights the presence of novel flow structures at the scale of the sublayer, with strong spanwise meandering motions, of 2-3 viscous wall units, indicating a highly unsteady and accelerating flow within. The probability distribution of accelerations shows a stretched exponential shapes characteristic of highly intermittent turbulence seen under isotropic flows. The presence of flow structures even at the scale of the sublayer, i.e., below y⁺~5, points to the effectiveness of roughness elements in modulating the large scale flow.

Laser-induced porous graphene on polyimide/PDMS composites and its kirigami-inspired strain sensor

Hao Wang, Zifeng Zhao, Panpan Liu, Xiaogang Guo

2021, 11(2): 128 -133. doi: 10.1016/j.taml.2021.100240

[Abstract] (248) [FullText HTML] (78) [PDF 2870KB] (4)

Abstract:
The laser-induced porous graphene (LIG) prepared in a straightforward fabrication method is presented, and its applications in stretchable strain sensors to detect the applied strain are also explored. The LIG formed on the polyimide/polydimethylsiloxane (PI/PDMS) composite exhibits a naturally high stretchability (over 30%), bypassing the transfer printing process compared to the one prepared by laser scribing on PI films. The PI/PDMS composite with LIG shows tunable mechanical and electronic performances with different PI particle concentrations in PDMS. The good cyclic stability and almost linear response of the prepared LIG's resistance with respect to tensile strain provide its access to wearable electronics. To improve the PDMS/PI composite stretchability, we designed and optimized a kirigami-inspired strain sensor with LIG on the top surface, dramatically increasing the maximum strain value that in linear response to applied strain from 3% to 79%.