Your search keyword '"stress concentration"' showing total 91 results

1. 凸形状マイクロストラクチャ-による シングルラップ接着接合継手の疲労亀裂進展抑制.

Author

堀 川 海 音, 安 岡 哲 夫, and 水 谷 義 弘

Subjects

CRACK propagation (Fracture mechanics), STRAINS & stresses (Mechanics), STRESS concentration, MICROSTRUCTURE, ADHESIVE joints, STRAIN energy, CYCLIC loads

Abstract

In this study, a convex micro-structure, single protrusion with a square profile, formed on adherend surfaces of single-lap adhesively-bonded joints as a crack propagation suppressor, and the performance of the convex structure was experimentally investigated by applying cyclic loads. Moreover, the change in crack propagation rate due to convex micro-structure was analytically discussed, focusing on strain energy release rate and stress field in the adhesive layer and the adherend. The experimental and analytical results revealed the crack propagation rate with convexity was lower than that without convexity around the convex micro-structure. In addition, the change ratio of crack propagation rate due to convex micro-structure did not depend on the test load levels. The reasons for suppressing crack propagation were considered the energy in the vicinity of the crack tip decreased due to the stress concentration around the convex microstructure and the limited displacement of the fractured adhesive interfered with the convex structure. [ABSTRACT FROM AUTHOR]

Published

2023

2. GLS モデルによる一方向CF/PP の温度依存強度特性の予測.

Author

田 井 稜 華, 沼 野 直 樹, 坂 上 賢 一, and 伊 崎 健 晴

Subjects

SHEARING force, STRESS concentration, STRAINS & stresses (Mechanics), YIELD stress, WEIBULL distribution

Abstract

In the present study, a matrix stress-strain relationship is calculated from the off-axis stress-strain relationship of CF/PP laminates by inverse analysis based on Eshelby model combined with Mori-Tanaka theory. Then, the stress-strain relationship and yield shear stress at various temperatures is estimated by viscoelastic characteristic. Next, the temperature dependence of strength and strength variation of unidirectional CF/PP are predicted from the matrix yield shear stress and Weibull distribution using the extended GLS model, which takes into account the existence of initial defects. Comparison of the predicted strength of CF/PP with the test results in previous studies shows the validity of the prediction method of the temperature dependence of strength by the extended GLS model. [ABSTRACT FROM AUTHOR]

Published

2023

3. Shape optimum design of porous structure for minimizing maximum thermal stress

Author

Mihiro TORISAKI and Masatoshi SHIMODA

Subjects

multi-scale optimization, homogenization method, shape optimization, h1 gradient method, periodic microstructure, min-max problem, kreisselmeier-steinhauser function, stress concentration, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

In this study, we propose a solution to a shape optimization problem for the strength design of porous structures under thermal loading. The homogenization method is used to bridge the macrostructure and the porous microstructures, in which the elastic and thermal expansion tensor are homogenized. The local thermal stress in the porous structure is minimized. By replacing the maximum thermal stress with a Kreisselmeier-Steinhauser function, the difficulty of non-differentiability of maximum stress is avoided. This problem is formulated as a distributed parameter optimization problem subject to an area constraint including the all microstructures. The shape gradient function for this design problem is derived using Lagrange multiplier method, the material derivative methods, which are independently defined for the sub-regions in the macrostructure and the adjoint variable method. The H1 gradient method is used to determine the optimal shape of the porous unit cell while reducing the objective function and maintaining smooth design boundaries. Effectiveness of the proposed method for minimizing the thermal stress of porous structures is confirmed by the numerical examples.

Published

2023

4. Out-of-plane bending stress intensity factor analysis of cracks in a strip using single-element strain gage

Author

Shigeru KUROSAKI and Jyo SHIMURA

Subjects

experimental stress analysis, strain gage, stress intensity factor, fracture mechanics, crack, experimental mechanics, stress concentration, nondestructive inspection, stress-strain measurement, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

In recent years, the authors have developed a dedicated strain gage (hereafter referred to as a K-value gage) and an analysis method that can analyze the stress intensity factor of a crack with a single element. The developed single-element K value gage can obtain the opening mode stress intensity factor of the simulated crack within ±5% of the theoretical value. In this study, using this single-element K-value gage, a simulated crack was inserted into one side edge of the strip and an attempt was made to analyze the stress intensity factor when an out-of-plane bending load was applied. M.L.Williams introduced the stress equation for the out-of-plane bending load acting on a strip crack. In this study, the stress equation was converted into the strain εθ equation, and the K-value gage equation was derived. The K-value gage formula defined a K-value gage grid angle of 104 degrees for a Poisson's ratio of 0.3. In order to examine the validity of the derived strain gage equation, out-of-plane bending experiments were carried out on strips with simulated cracks inserted. When a/W=0.2 and 0.3, the crack length a with respect to the strip width W was obtained within ±10% of the theoretical value. When a/W=0.1, the error was 10-15%.

Published

2023

5. Effect of loading type on fatigue property of specimens treated by cutting and rubbing process

Author

Terutoshi YAKUSHIJI, Dai AKAMINE, Tsubasa TOKUZUMI, Kyohei TAKEO, and Masahiro GOTO

Subjects

surface treatment, residual stress, rubbing process, friction process, circumferential notch, stress concentration, nanocrystal grain, rotating bending fatigue, tension compression fatigue, torsion fatigue, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

Aiming for a result to improve fatigue strength, “cutting and rubbing process” which is a kind of surface treatment was used for forming a round-bar smooth-specimen, showing drastically enhanced rotating-bending fatigue strength. On the other hand, actual machine components and structures invariably contain geometrical irregularities, such as fillets, keyways, screw threads, and holes. Fatigue cracks initiated from such stress raisers, indicating that the validity of the cutting and rubbing process on fatigue strength of specimen with a stress raiser should be examined. In this study, fatigue tests of smooth and notched specimens finished by the cutting and rubbing process were conducted under some loading types including rotating-bending, tension-compression and torsion loading. Results showed that fatigue strength of notched specimens was significantly enhanced compared to that of smooth specimens under rotating-bending and tension-compression loads. In other words, the cutting and rubbing processing was more effective in stress raisers than the smooth surface. The physical background on the effect of loading type on the fatigue strength of the cutting and rubbing processed specimen was discussed based on the fracture origin, microstructure in the surface layer, stress gradient caused by both loading type and notch.

Published

2023

6. The opening mode stress intensity factor extraction method from mixed mode crack using single element strain gage.

Author

Shigeru KUROSAKI, Jyo SHIMURA, Syuusaku YAMAJI, Mitsutaka KANEHIRA, and Takeshi SHIMURA

Subjects

experimental stress analysis, strain gage, stress intensity factor, fracture mechanics, crack, experimental mechanics, stress concentration, nondestructive inspection, stress-strain measurement, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

Previously, the authors developed a strain gage (K-value gage) that can analyze the open mode stress intensity factor exclusively. This K-value gage was designed as a one-element strain gage with a gage width of 1 mm and a grid angle of 104° curvature. This paper presents an analysis method that can extract only the opening mode stress intensity factor from mixed mode (opening + shearing) cracks using the developed K-value gage. The extraction analysis method using this K-value gage was derived for the case of Poisson's ratio of the material to be measured 0.3. At the same time, Poisson's ratio led to use other than 0.3. Furthermore, this paper verified the validity of the proposed analysis method from experiments using a K-value gage. In the comparative verification experiment with the theoretical value, a tensile test was performed by inserting simulated cracks of the same length with only the inclination angle changed in a flat plate test piece. As a result, the experimental values of the aperture mode stress intensity factors were obtained within ±10% of the theoretical values.

Published

2022

7. Development and analysis method of single element strain gage for stress intensity factor analysis in crack opening mode (2nd report, development of grid angle 104° K value gage)

Author

Shigeru KUROSAKI, Jyo SHIMURA, Syuusaku YAMAJI, Mitsutaka KANEHIRA, and Takeshi SHIMURA

Subjects

experimental stress analysis, strain gage, stress intensity factor, fracture mechanics, crack, experimental mechanics, stress concentration, nondestructive inspection, stress-strain measurement, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

This paper shows the development and analysis method of a single element strain gage (K value gage) used to analyze the stress intensity factor of mode I (opening type) cracks. The K-value gage reported in the previous report collected the strain εθ with a grid angle of 52 °, and was able to obtain the stress intensity factor within an error of 10% from the theoretical value. The purpose of this study was to develop a K-value gage with even higher accuracy. As a result, the developed single-element K-value gage had a total grid angle of 104 ° extended to ± 52° from the crack tip extension line. Using the developed 104° K-value gage, two types of experiments were conducted to investigate the analysis accuracy of the stress intensity factor. One is a comparative experiment with a conventional grid angle 52 ° K value gage. The second was to change the simulated crack length of the test piece by three types. The following was found from the experiment. (1) The 52 ° K-value gage had a maximum error of 10% from the theoretical value, while the 104 ° K-value gage was obtained within a maximum of 5%. (2) All three types of test pieces with different simulated crack lengths were obtained within 5% of the theoretical value and the maximum error.

Published

2022

8. Development and analysis method of single element strain gage for stress intensity factor analysis in crack opening mode (Verification of analysis accuracy by simulated crack)

Author

Shigeru KUROSAKI, Jyo SHIMURA, Syusaku YAMAJI, Mitsutaka KANEHIRA, and Takeshi SHIMURA

Subjects

experimental stress analysis, strain gage, stress intensity factor, fracture mechanics, crack, experimental mechanics, stress concentration, nondestructive inspection, stress-strain measurement, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

A dedicated strain gage has been developed to measure the stress intensity factor of cracks. Conventional strain gages dedicated to stress intensity factor analysis have been made by combining multiple elements into a single gage. Therefore, it took time and effort to analyze the stress intensity factor. Therefore, in this research, we have developed a dedicated strain gage that can analyze the stress intensity factor more easily than before with only one gage of one element. The developed strain gage analysis formula uses the strain component εθ formula at the crack tip. We focused on the gage angle θ that brings the second term of the crack analysis strain component εθ close to 0. By setting the second term to 0, the stress intensity factor of the first term can be analyzed accurately in consideration of the second term. The developed gage has a donut shape with radii r1 and r2 and a width of 1 mm with the crack tip as the origin, and the gage grid angle has an angle from 0 ° to 52 °. A tensile test piece with a crack opening mode load was manufactured and a tensile experiment was conducted. The experimental value of the stress intensity factor was obtained within an error of ±10% from the theoretical value.

Published

2022

9. 光コヒーレンストモグラフィーによる Al2O3 顆粒の一軸加圧下における 粉体層中の空隙の形態変化過程のその場観察.

Author

高橋　拓実 and 多々見　純一

Subjects

UNIVERSAL testing machines (Engineering), OPTICAL coherence tomography, STRESS concentration, FUNCTIONAL foods, PRODUCT quality, POWDERS

Abstract

Uniaxial pressing is a utilized technique to prepare powder compacts in regions of ceramics, metal, drug, and functional food. On the other hand, it is known that the inhomogeneous structures are induced by stress distribution resulting from applying the anisotropic stress field to the powder bed and they become the origin which forms defect degrading the performance of products. However, the generation process of inhomogeneous structures has not been clarified experimentally. Directly understanding the formation mechanism of the internal structure during uniaxial pressing is very important to control the particle-assembled structure in the powder bed and the quality of products. In this work, the change process in void morphology under uniaxial pressing was observed dynamic-two-dimensionally and intermittent-three-dimensionally by the novel observation system composed of swept-source optical coherence tomography (SS-OCT) and material testing machine. Moreover, the detected voids were evaluated quantitively to directly clarify particle-packing behavior on the initial stage of pressing. [ABSTRACT FROM AUTHOR]

Published

2020

10. Investigation of continuum damage mechanics model without element size sensitivity

Author

Satoshi HIROSE and Yutaka TOI

Subjects

damage mechanics, stress concentration, mesh dependence, stress sensitivity, strain gradient, fracture, crack growth, damage localization, constitutive equation, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

A discontinuous material behavior such as ductile fracture and fatigue failure is predicted actively in various fields by FEM. There is continuum damage mechanics as a method to evaluate the discontinuous material behavior in a framework of continuum mechanics. However, the predicted behavior based on the method depends strongly on finite element size. Then, improvement of damage evolution equation and damage limit equation in continuum damage mechanics is discussed to reduce the mesh-dependence. These equations are extended based on finite element size and evaluated strain gradient. The predicted material property such as fracture strain in tensile test based on new equations corresponds to experimental result. Additionally, the prediction accuracy is higher than conventional mesh-independence model. Especially, the higher the tensile strength of material is, the higher the prediction accuracy is.

Published

2017

11. Strain rate concentration factor in comparison with stress concentration factor of a circumferential notch in a round bar specimen

Author

Nao-Aki NODA, Daichi AKAGI, Yunong SHEN, Rei TAKAKI, Tomohiro IKEDA, Yoshikazu SANO, and Yasushi TAKASE

Subjects

tensile properties, stress concentration, notch, impact strength, strain rate, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

High-speed tensile testing is now being recognized as a standard testing method for evaluating the impact strength of engineering materials. The impact speeds of Izod and Charpy tests cannot be controlled and therefore do not correspond to the real failure of real products. The brittle-ductile transition of structural materials is affected by the temperature and loading speed. In the high-speed tensile test, it is necessary to obtain the strain rate at the notch root accurately to understand the effect of impact load. For smooth specimens, the strain rate can be determined from the tensile speed u/t and specimen length l as εsmooth = u/tl. For notched specimens, however, the strain rate at the notch root εnotch should be analyzed accurately. In this study, therefore, the strain rate concentration factor defined as Ktε = εnotch/εsmooth is studied with varying the notch geometry. To predict the strain rate concentration factor Ktε accurately, the relationship between Ktε and the stress concentration factor Kt* = σmax/σgross is investigated. Here, σgross is the remote tensile stress and P is the tensile load. It is found that the strain concentration factor Ktε can be estimeted from stress concentration factor Kt* when the relative notch depth 2t/D≦0.5 (t : notch depth, D : the specimen diameter).

Published

2017

12. 微結晶粒セラミック材料における低温高速超塑性の可能性.

Author

平賀　啓二郎, 金　炳男, 森田　孝治, 吉田　英弘, 目　義雄, and 古瀬　裕章

Subjects

SUPERPLASTICITY, CAVITATION, KIRKENDALL effect, NANOCRYSTALS, CERAMIC materials, PARTICLE size distribution, DOPING agents (Chemistry)

Abstract

For attaining high-strain-rate superplasticity (HSRS) in ceramic materials, prerequisites are described on the basis of existing knowledge about high-temperature plastic deformation and intergranular cavitation mechanisms. The knowledge suggests that a combination of grain-size refinement to 100-200 nm or smaller and enhanced diffusion caused by doping may highly enhance stress-relaxation around triple junctions and may lead to HSRS at temperatures lower than 1250-1300°C in structural ceramics. From this point of view, recent studies are reviewed and discussed on ceramic superplasticity at strain rates higher than 1 × 10−2 s−1. Attention is also placed on the fabrication of materials with nanosized grains and the resultant superplastic properties. [ABSTRACT FROM AUTHOR]

Published

2017

13. Effect of crystallographic properties on low cycle fatigue crack initiation at elevated temperature for Ni-based directionally solidified superalloy with small holes

Author

Takashi YOKOYAMA and Masaru SEKIHARA

Subjects

low cycle fatigue, ni-based superalloy, stress concentration, ebsd, crystal plasticity, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

Low cycle fatigue tests at elevated temperature were conducted on a Ni-based directionally solidified superalloy with small holes subjected to transverse loading. To investigate the effect of the arrangement and the orientation of crystal grains on the crack initiation, the electron back-scatter diffraction (EBSD) method was applied on the surface of the tested specimens. In addition, finite element analysis that considered the plastic behavior of crystal grains was performed to evaluate the relationship between the crack initiation and the local stress that developed along the hole edges. The results are summarized below. It was shown that the number of cycles to crack initiation tended to be small along the hole edges located on the grain boundaries by classifying the hole edges according to the position of the hole edge and the grain boundary. In addition, it was small along the hole edges located in the grain whose secondary axis was more inclined than the grain located in the opposite surface. The results of FEM analysis revealed that high stress developed along those hole edges. The location where high stress developed correlated with the number of crack initiation cycles not only among the hole edges in one specimen but also among the specimens subjected to different nominal strain range.

Published

2016

14. Tension of an infinite solid containing an elastic spherical inclusion (Mixed boundary-value problem in consideration of interference-fit state)

Author

Kounan SYU, Hiroyuki HAYASHI, and Terumi YAMAMOTO

Subjects

elasticity, mixed boundary-value problem, contact stress, stress concentration, spherical inclusion, infinite elastic solid, interference, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

This report deals with the influence of the interference between an elastic sphere and a spherical cavity on the stress distribution and displacement around cavity, which has simply a smooth elastic sphere, in an elastic solid under tension at infinity. The contact stress between the sphere and the cavity is expressed with series of Legendre functions, and the stress and displacement are numerically analyzed by point matching method. Using the numerical results for the elastic solid, the effects of interference and loads are shown on the stresses around the spherical cavity boundary. The main results are as follows: (1) The contact region and stress distribution of the elastic solid are independent of the magnitude of load, when diameter of sphere and spherical cavity are initially the same. (2) When diameters of them are not same, the contact region and stress distribution of the elastic solid vary with a change in magnitude of load.

Published

2016

15. Fatigue strength for bolts and nuts having slight pitch difference considering incomplete threads of nut

Author

Nao-Aki NODA, Yoshikazu SANO, Xin CHEN, Hikaru MARUYAMA, Huan WANG, Ryota FUJISAWA, and Yasushi TAKASE

Subjects

strength, material testing, stress concentration, fatigue, screw, finite element method, contact problem, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

The high strength bolts and nuts are widely used in engineering structures. To investigate the pitch difference on the fatigue strength of bolt, a slight pitch difference is considered between the bolt and nut. Here, the pitch of the nut is α μm larger than the pitch of the bolt. The fatigue experiment is conducted with varying pitch difference. The results show that the fatigue life is extended to about 1.5 times of the one of normal bolt and nut by introducing the suitable pitch difference under the high stress amplitude. According to the detailed observation on the fractured specimens, it is found that the fractured positions and the crack distributions vary depending on the pitch difference. To clarify the improvement mechanism of the fatigue strength, the finite element method is applied to calculate the stress amplitude and mean stress at each bottom of bolt threads. It is found that the finite element analytical model considering the incomplete nut threads is useful for predicting the crack initiation under different pitch difference introduced.

Published

2015

16. Disclination model applied to elastic incompatibility at grain boundary triple line (Application of finite element model of disclination)

Author

Takafumi HOSOYA, Hiroyuki KATO, and Kazuaki SASAKI

Subjects

stress concentration, disclination, dislocation, elasticity, non-uniform deformation, isotoropy, anisotoropy, tricrystal, grain boundary triple line, finite element method, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

We examined the stress concentration that would occur at grain boundary triple lines during deformation in two copper tricrystals with [011] tilt boundaries; one was a symmetrical tricrystal with respect to the loading axis and the other was an anti-symmetrical one. In principle, the finite element method can provide solutions with prescribed amount of precision for the anisotropic elasticity problem. It was shown that a close approximation was possible by means of a disclination model in elastically homogeneous material. This disclination model was numerically solved with the finite element method proposed in a previous paper (Hosoya, Kato, Sasaki, Trans. JSME, Vol.80, No.819 (2014 ). It was concluded that the disclination model is appropriate for estimating the stress concentration at the grain boundary triple lines in deformed polycrystals.

Published

2015

17. Strain Rate Concentration Factor of Notched Flat Bar Specimens

Subjects

Notch, Tensile Properties, Stress concentration, Strain rate(D3), Impact strength

Abstract

高速引張試験において衝撃強度を評価するためには，切欠き形状とひずみ速度集中係数の関係が重要である．そこで，切欠きを有する平板試験片の切欠き形状を変え切欠き底のひずみ速度集中係数を計算し，応力集中係数よりひずみ速度集中係数を求められることを示した．さらに，その比は開き角に依存しないこともわかった．

Published

2018

18. The Process of Self-Efficacy for Reducing Depression is Mediated by Concentration on Distraction.

Author

Megumi OIKAWA, Keisuke YAMATSUTA, and Shinji SAKAMOTO

Subjects

*SELF-efficacy, *STRESS concentration, *DISTRACTION, *MENTAL illness prevention, *AFFECTIVE disorders

Abstract

This study investigates the process of self-efficacy for reducing depression by focusing concentration on distractions as a mediator. Self-efficacy was one of the effective factors for preventing depression in previous studies. In the present study, participants completed a questionnaire twice with a one-month interval. The results suggest that self-efficacy reduced depression by means of enhancing concentration on distraction. The results also suggest that high depression at Time 1 affected high depression at Time 2, and that high interpersonal stressors during the one-month interval affected low concentration on distraction and high depression at Time 2. [ABSTRACT FROM AUTHOR]

Published

2013

19. Simulations of stress distribution in glenohumeral joint at pitching posture -a correlation between MRI and Finite Element Method-.

Author

Ishii, T., Mukai, N., and Miyakawa, S.

Subjects

GLENOHUMERAL joint, STRESS concentration, FINITE element method, MAGNETIC resonance imaging, SHOULDER injuries

Abstract

We performed simulations of stress distribution in the glenohumeral joint in the late cocking phase using the Finite Element Method analysis (FEM) and investigated the correlation between MRI and FEM. In the simulation increase of stress was seen in the supra-lateral side of the humeral head and posterior portion of the glenoid when we positioned the humerus in horizontal extension and external rotation in the glenohumeral joint. Distribution of lesions caused by internal impingement in MRI was almost the same as that of stress simulated by FEM analysis. Still there are many problems in predicting throwing shoulder injury by pitching form, but FEM analysis could provide a clue to the development of a prediction method for throwing shoulder injury [ABSTRACT FROM AUTHOR]

Published

2010

20. Root Fracture Mechanism of Foundation Restoration.

Author

Takahashi, Hidekazu

Subjects

BONE fractures, TOOTH root diseases, DENTAL fillings, BRUXISM, DENTISTS

Abstract

The article reports on the factors that caused root fracture of endodontically treated teeth with a foundation restoration in Japan. It reveals the importance of minimal tooth grinding in the prevention of root fracture, and the association between the design of the foundation restoration without root fracture and the elimination of the fundamental restoration. It notes the need for dentists to create a suitable foundation restoration with enough retention.

Published

2001

21. The Influence of Mesial Inclination of Implant on Stress Distribution around Implant.

Author

Jun-ichi Abe, Kawawa, Tadaharu, Fakunaga, Hideki, and Warita, Kenji

Subjects

BONE resorption, DENTAL implants, FINITE element method, STRESS concentration, MALOCCLUSION

Abstract

The article presents a study on the influence of implant mesial inclination on dental implant stress distribution. It mentions the construction of a two-dimensional finite element models including a bridge-shaped superstructure, implants, cortical bone, and cancellous bone. Implant mesial inclination on three points of the occlusal plane were determined and stress distributions were calculated. Study results and recommendations are also presented.

Published

2001

22. Three-Dimensional Photoelastic Stress Analysis on Posterior Hybrid Ceramics Bridge Restorations.

Author

Asada, Toshiyuki, Shinya, Akiyoshi, and Yokozuka, Shigeo

Subjects

PHOTOELASTICITY, THREE-dimensional imaging, STRESS concentration, DENTAL ceramics, DENTAL ceramic metals

Abstract

The article focuses on the study concerning posterior hybrid ceramics bridge restorations. The study involves three-dimensional photoelastic and its analyzation of the stress distribution of hybrid ceramics bridge. It compares two types of bridges one is the type I which is composed of hybrid ceramics alone, the other Type II a metal frame inside. It mentions that the bridge models were cut into several parts including lingual, buccal and central.

Published

2000

23. Stress Distribution in Tooth Supported Removable Bridge with Long Saddle: Part 1. Stress Analysis at Abutment Teeth and Alveolar Bone by 2-Dimensional Finite Element Method.

Author

Inoue, Yoshihisa, Kuroiwa, Akihiro, Ogata, Akira, Suzuki, Akira, Ohno, Takafumi, Igarashi, Yoshimasa, and Ohshima, Kazunari

Subjects

STRESS concentration, BRIDGE abutments, DENTAL occlusion, DENTAL abutments, FINITE element method, PROSTHODONTICS

Abstract

The article presents a study concerning the examination of the displacement of model in a supported tooth and occlusal stress distribution. It assesses the presence and absence of the bound saddle and the rigidity of the removable bridge using a two-dimensional finite element method. It states that the stress distribution was more dispensed in the plate type removable bridge on the abutement teeth.

Published

1998

24. In viva Assessment of Occlusal Stress Distribution in Free-end Saddle Removable Partial Dentures Part 2 Connecting Rigidity Affecting the Stress Distribution in Free-end Saddle Removable Partial Dentures.

Author

Ogata, Akira

Subjects

STRESS concentration, REMOVABLE partial dentures, PARTIAL dentures, ORTHODONTICS, DENTAL abutments

Abstract

The article discusses the study that examines the effect of connecting rigidity on the stress distribution in free-end saddle removable partial dentures. The denture base supporting load ratio in relation to the connecting rigidity was analyzed. The study reveals a close relationship between connecting rigidity of abutments or denture saddle of distal extension of removable partial denture (RPD) and occlusal force distribution between abutments and residuall ridges.

Published

1998

25. Fatigue Strength for Bolts and Nuts Having Slight Pitch Difference Considering Incomplete Threads of Nut

Subjects

Contact problem, Finite element method, Material testing, Screw, Stress concentration, Strength, Fatigue

Abstract

The high strength bolts and nuts are widely used in engineering structures. To investigate the pitch difference on the fatigue strength of bolt, a slight pitch difference is considered between the bolt and nut. Here, the pitch of the nut is α μm larger than the pitch of the bolt. The fatigue experiment is conducted with varying pitch difference. The results show that the fatigue life is extended to about 1.5 times of the one of normal bolt and nut by introducing the suitable pitch difference under the high stress amplitude. According to the detailed observation on the fractured specimens, it is found that the fractured positions and the crack distributions vary depending on the pitch difference. To clarify the improvement mechanism of the fatigue strength, the finite element method is applied to calculate the stress amplitude and mean stress at each bottom of bolt threads. It is found that the finite element analytical model considering the incomplete nut threads is useful for predicting the crack initiation under different pitch difference introduced.

Published

2015

26. 既存屋内運動場におけるはり継手補強ディテールの検討

Subjects

Seismic retrofitting, Stress concentration, FEM analysis, Beam joint

Abstract

The many buildings that have been built in the new seismic design method previously, seismic perform-ance is very low. These buildings was severely damaged in the earthquake. So seismic retrofitting is required. The connection of the old steel frame buildings vulnerable, reinforcement is required. However, details of the repair method is not been decided. An object of this study is the determination of the joint de-tails. Parameter to consider is the weldability and the angle of the reinforcing plate. From this result, we de-termined to 30 degrees the angle, be 40 mm the mounting position of the tab.

Published

2015

27. Stress Concentration due to Defects in Honeycomb

Subjects

Honeycomb, Stress Concentration, Defect, Elasticity, Elliptical Inclusion

Abstract

In this paper, the mechanism of stress concentration due to defects in honeycomb sandwich structure is studied by using finite element method. It is found that the stress concentrantion can be expressed as a function of Ectc=Eptp, where tc and tp are the thickness of core and plate, respectively, and Ec and Ep are the Young's modulus of core and plate, respectively. Also, it is found that the stress concentrantion can be evaluated by an approximation of an elliptical inclusion. The validly of this technique is verified through comparison of the evaluation values with the numerical results obtained by FEM.

Published

2013

28. Evaluation of Seismic Damage to the Mound of Takamatsuzuka Tumulus Based on Dynamic Finite Element Analysis

Subjects

応力集中, 加速度増幅, 三次元動的有限要素解析, 地盤と石材の相互作用, 高松塚古墳, Takamatsuzuka tumulus, three dimensional dynamic finite element analysis, amplification of acceleration, stress concentration, interaction between the mound and the chamber stones

Abstract

Innumerable cracks and fissures caused by huge earthquakes were found on the excavated walls inside the mound of Takamatsuzuka Tumulus during archaeological investigation. The largescale excavation prior to the dismantling of the stone chamber in 2006 gave additional information about the three-dimensional distribution of those cracks and fissures. Serious ground motion due to huge subduction earthquakes hitting Japan every 100 to 140 years as well as nearfault earthquakes possibly caused the damage to the tumulus mound. Thus, seismic stability is of importance for the conservation of tumulus mounds made of soil without artificial reinforcement. In this study, a series of three-dimensional dynamic finite element analyses was conducted for the mound of Takamatsuzuka Tumulus to investigate the possibility of the occurrence of cracks and fissures induced by the outer forces of earthquakes. Based on archeological investigation, realistic modeling for the tumulus structure was conducted. Calculated performance shows that the natural period of Takamatsuzuka Tumulus that can generally be measured for near field earthquakes is 0.15 s. This means that such a small mound as Takamatsuzuka Tumulus is more fragile to near field earthquakes than subduction earthquakes. Serious amplification of acceleration can be seen in the tumulus mound. The response acceleration derived on the mound becomes much larger than the input acceleration monitored in the original ground. Calculated results also exhibit that serious stress concentration is found at the foot of the mound and at the boundary of the mound and the chamber stones, possiblycausing the occurrence of cracks in the mound of Takamatsuzuka Tumulus.

Published

2011

29. Investigation and Analysis of the Cause of Failure Accident of Wind-lens Turbine Blades

Subjects

Stress Concentration, Crack, Joint, Beach Mark, Hub, Striation, Wind Velocity, Fatigue Failure, Fracture Surface, Wind-lens Turbine, Blade

Abstract

An investigation and analysis of failure accidents of Wind-lens turbine blades was presented. Due to the failure of the electric loading device, Wind-lens turbine was running under non-loading conditions for some minutes. Then, the wind velocity U around Wind-lens turbine reached U_ =19m/s and the tip velocity V_ of blades reached V_ 152m/s. Fatigue crack was easily initiated at the corner of fillets of joints connecting blades to hub where stress concentration was caused. The bolts were subjected to a large load by application of vibrational stress and torsional moment. The clearance between the head of bolts and hub was expanded. To investigate the fracture surface, the beach marks and striations characteristic of fatigue fracture were obviously observed. The number of cycles from crack initiation to final failure was calculated on the basis of fracture mechanics by observing the fatigue striation in the vicinity of fracture origin. Vibrational service stress amplitudes applied at the joint of blades and hub were much larger than the inherent fatigue strength of blade's material, ABS resin. In order to prevent such a failure accident of a small wind turbine generator, the recommended shapes of blades and hub were proposed.

Published

2010

30. Dynamic Finite Element Analyses on the Mound of Takamatsuzuka Tumulus

Subjects

応力集中, 地震由来の亀裂, Takamatsuzuka Tumulus, Earthquake Induced Crack, Three Dimensional Dynamic Finite Element Analysis, Stress Concentration, Interaction Between the Mound and the Chamber Stones, 三次元動的有限要素解析, 地盤と石材の相互作用, 高松塚古墳

Abstract

Innumerable cracks and fissures caused by huge earthquakes were found inside the mound of Takamatsuzuka Tumulus. Those cracks and fissures were originally found on the excavated walls during archaeological investigation. Furthermore, the large-scale excavation prior to the dismantling of the stone chamber in 2006 gave additional information about the threedimensional distribution of those cracks and fissures. Serious ground motion due to huge subduction earthquakes hitting Japan every 100 to 140 years possibly caused the damage to the tumulus mound. The instability of the tumulus mound is one reason it was judged impossible to preserve the mural paintings in situ. This paper presents the results of a series of three-dimensional dynamic finite element analyses conducted for the mound of Takamatsuzuka Tumulus to investigate the possibility of the occurrence of cracks and fissures induced by the outer forces of earthquakes. Calculated performance shows that the natural period of Takamatsuzuka Tumulus is 0.17 s. and that this value is the one that is generally measured for near field earthquakes. This means that such a small mound as Takamatsuzuka Tumulus is more fragile to near field earthquakes than subduction earthquakes. Calculated results also show that serious stress concentration, which could have caused the occurrence of cracks and fissures in the mound of Takamatsuzuka Tumulus, is found at the foot of the mound and at the boundary of the mound and the chamber stones.

Published

2010

31. Stress Reduction Effect and Anti-loosening Performance of Outer Cap Nut by Finite Element Method

Subjects

Stress Concentration, Fixing Element, Finite Element Method, Machine Element, Screw Thread, Contact Problem, Bolted Joint

Published

2006

32. An introduction to force with the observation of inhomogeneous deformation at the intended break

Author

千葉大学・教育学部

Subjects

応力集中, 初等物理教育, finite element method, photoelastic effect, stress concentration, 不均一変形, 光弾性効果, elementary physics education, inhomogeneous deformation, 有限要素法

Abstract

初等物理教育において,力を定量的に導入する直前の段階として,固体にかかる応力が分布する「不均一変形」を観察させる教材を示す。身の回りには,大きく変形し,壊れることによって役立つものが数多く存在している。それを学生自らが探り出し,どのようにして狙い通り壊れるのかを観察・探求するのは,物理が特別なモデルの上でのみ成り立つという意識を打破するのに有効である。また,光弾性効果を使った演示実験により,講義の中で現象を再現しながら説明することができる。さらに,有限要素法によるシミュレーションと照合する中で,実験だけで理解しようとするのは危険であることがわかった。不均一な応力場への理解は,教える側も足りないことが多いので,教材としては,課題探求・演示実験・シミュレーションの三点をセットにするのが望ましい。, The inhomogeneous distribution of deformation in stress-applied solids is one of the quite usual physical phenomena. It attracts many students, because the drastic change of the form by their force is very impressive. The homework to find it and to observe how successfully the solid is destroyed should be helpful to correct their misunderstanding that the physics only conserved in special unrealistic models. The understanding of the phenomenon is of cause so difficult that the demonstration experiment should be accompanied. Using the photoelastic experiment, the homogeneous area in the sample is now clear and the smooth shift to the physics of the stretched ropes under homogeneous stress, which is a tool of an introduction of force, becomes easy. However, the photoelastic effect with large birefringence is essentially nonlinear, and the geometrical pattern of the photoelastic image does not correspond to the distribution of deformation. Accordingly, the simulation using the finite element method in additi

Published

2006

33. Stresses in an Elastic Strip Having a Circular Inclusion under Tension

Subjects

Stress Concentration, Tension, Infinite Strip, Circular Inclusion, Elasticity

Abstract

This paper presents an analytical solution for an infinite strip having a circular inclusion when the strip is subjected to tension at infinity. In the analysis, the inclusion is assumed to be perfectly bonded and be allowed to slide. The analysis is based on the Papcovich Neuber stress function approach and the solution is obtained by the proper combination of harmonic function in integral forms and infinite series. The boundary conditions at the interface uniting the strip and the inclusion are satisfied using the relations between the polar and Cartesian harmonics. The numerical results obtained from the proposed method are illustrated for various stiffness ratio and sizes of the inclusion.

Published

2006

34. In-Plane Bending of an Infinite Strip with a Circular Inclusion

Subjects

Stress Concentration, Bending, Infinite Strip, Circular Inclusion, Elasticity

Abstract

This paper contains an analysis of the stress and displacement distribution arising in a strip with a circular inclusion when the strip is subjected to bending at infinity. Two types of inclusion, i.e., perfect bonding and sliding inclusion are treated in this paper. The solution which is based on the Papcovich-Neuber displacement potentials is obtained by combining the harmonic potentials in integral forms and infinite series. The boundary conditions of the problem are fully satisfied using the relationships between the harmonic functions of Cartesian and polar coordinates. The effect of the inclusion on the stress and displacement are given in the form of graphs to show the availability of the present method.

Published

2006

35. Prediction of Fatigue Crack Propagation Path from a Pre-Crack under Combined Torsional and Axial Loading

Author

Yoshiaki Akiniwa, Hiroki Takahashi, Takuya Kato, and Keisuke Tanaka

Subjects

Body force, Materials science, Deformation (mechanics), Combined Stress, business.industry, Mechanical Engineering, Fracture Mechanics, Crack tip opening displacement, Fracture mechanics, Structural engineering, Crack growth resistance curve, Crack closure, Mechanics of Materials, Crack Propagation Path, mental disorders, General Materials Science, Composite material, Crack Face Contact, business, Stress intensity factor, Fatigue, Body Force Method, Stress concentration, Crack Propagation

Abstract

Fatigue tests of crack propagation from a pre-crack in thin-walled tubular specimens made of a medium-carbon steel were performed under cyclic torsion with and without superposed static or cyclic axial loading. The stress ratio of cyclic loading was-1. The experimental path of fatigue crack propagation from a pre-crack was compared with the predictions based on the maximum tangential stress criterion. The direction of fatigue crack propagation was perpendicular to the direction of the maximum of the range of the tangential stress, Δσ*θmax, near the crack tip determined from the stress intensity factor which was calculated by considering the contacts of crack faces at the minimum load. The stress intensity factor calculated from the actual crack path by using the body force method showed that the mode II stress intensity factor range quickly got close to zero after a small amount of crack extension. In other words, fatigue cracks propagate to satisfy the local symmetry of the cyclic components of crack-tip deformation.

Published

2005

36. Convenient Stress Concentration Formula Useful for Any Shape of Notch in a Round Test Specimen : Torsion of a Round Bar Having a V-Shaped and Circular-Arc Notch

Subjects

Test Specimen, Torsion, Stress Concentration, Numerical Analysis, Notch, Fatigue, Body Force Method

Abstract

In this work, stress concentration factors (SCFs) of a round bar with a circular-arc or V-sharped notch K_t are considered on the basis of exact solutions for special cases and accurate numerical results. First, for the limiting cases of deep and shallow notches, the body force method is used to calculate the SCFs; then, the formulas are obtained as K_ and K_. On the one hand, upon comparison of K_t and K_. it is found that K_t is nearly equal to K_ if the notch is deep or blunt. On the other hand, if the notch is sharp or shallow, K_t is mainly controlled by K_ and the notch depth. The notch shape is classified into several groups according to the notch radius and notch depth; then, the least squares method is applied for calculation of K_t/K_ and K_t/K_. Finally, a set of convenient formulas useful for any shape of notch in a round test specimen is proposed. The formulas yield SCFs with less than 1% error for any shape of notch. The effect of notch opening angle on the SCF is also considered for the limiting cases of deep and shallow notches.

Published

2004

37. Stress Concentration of an Ellipsoidal Inclusion of Revolution in the Vicinity of a Bimaterial Interface

Subjects

Singular Integral Equation, Stress Concentration, Numerical Analysis, Ellipsoidal Inclusion, Elasticity, Body Force Method

Abstract

This paper deals with a stress concentration problem of an ellipsoidal inclusion of revolution in a bimaterial body under tension. The problem is formulated as a system of singular equations with Cauchy-type or logarithmic-type singularities, where unknowns are densities of body forces distributed in the r-and z-directions in bimaterial boodies having the same elastic constants of those of the given problem. I order to satisfy the boundary conditions along the ellipsoidal boundary, four fundamental density functions proposed in the previous paper are used. Then the body force densities are approximated by a linear combination of fundamental density functions and polynomials. The present method is found to yield rapidly converging numerical results for stress distribution along the boundaries of both the matrix and inclusion even when the inclusion is very close to the bimaterial interface. Then, the effect of bimaterial surface on the stress concentration factor is discussed with varying the distance from bimaterial interface, shape ratio, and elastic ratio.

Published

2003

38. Stress Concentration of an Ellipsoidal Inclusion of Revolution in a Semi-Infinite Body under Biaxial Tension

Subjects

Singular Integral Equation, Stress Concentration, Numerical Analysis, Ellipsoidal Inclusion, Diaxial Tension, Semi-Infinite Body, Elasticity, Body Force Method

Abstract

This paper deals with a stress concentration problem of an ellipsoidal inclusion of revolution in a semi-infinite body under biaxial tension. The problem is formulated as a system of singular integral equations with Cauchy-type or logarithmic-type singularities, where unknowns are densities of body forces distributed in the r-and z-directions in semi-infinite bodies having the same elastic constants of the matrix and inclusion. In order to satisfy the boundary conditions along the ellipsoidal boundary, four fundamental density functions proposed in the previous paper are used. Then the body force densities are approximated by a linear combination of fundamental density functions and polynomials. The present method is found to yield repidly converging numerical results for stress distribution along the boundaries of both the matrix and inclusion even when the inclusion is very close to the free boundary. Then, the effect of free surface on the stress concentration factor is discussed with varing the distance from the surface, shape ratio, and elastic ratio. Also the present results are compared with the ones of an ellipsoidal cavity in a semi-infinite body.

Published

2003

39. Notch Effects on Impact Characteristics of Spheroidal and Compacted Vermicular Graphite Cast Irons with Various Matrix

Subjects

Stress Concentration, Charpy Impact Characteristics, Notch Factor, Ferrite, Graphite Nodularity

Published

2002

40. Characteristics of Elasticity of Circular Hole Void Slab and Derivation of Design Code of Its Thickness

Author

MOROOKA, Shigehiro

Subjects

設計式, void slab, design code, 応力集中, 直交異方性, ボイドスラブ, 円孔, 剛性評価, circular hole, ortho-tropic, stiffness estimation, stress concentration

Abstract

本論では，円孔ボイドスラブ構造について，曲げ剛性および応力集中の評価を行う評価係数(正確にはボイド孔直径-スラブ厚比の関数)を導入し，これらの係数によりボイドスラブを直交異方性板として解析できることを示す。続いて，この直交異方性板を等方性板として扱えることを示し，そこから導かれる解析的な式を用いて，孔の有無により生じる鉛直変位等の弾性力学的な性状の違いを述べる。また，RC規準と同等な手法によりスラブ厚の算定式を導出し，孔の大きさによる有効スパンヘの影響を調べる。確にはボイド孔直径-スラブ厚比の関数)を導入し，これらの係数によりボイドスラブを直交異方性板として解析できることを示す。続いて，この直交異方性板を等方性板として扱えることを示し，そこから導かれる解析的な式を用いて，孔の有無により生じる鉛直変位等の弾性力学的な性状の違いを述べる。また，RC規準と同等な手法によりスラブ厚の算定式を導出し，孔の大きさによる有効スパンヘの影響を調べる。, In the first part of this paper, the characteristics of the bending rigidity of the void slab and stress concentrations are confirmed and clarified by direct numerical method. These characteristics are estimated by the coefficients that are obtained in accordance with void diameter-thickness ratio. In the second part, it is shown that this ortho-tropic slab can be treated as an isotropic slab.Using the analytical equation, the difference between characteristics of elasticity by the existence of the holesuch as the vertical displacement is described. Finally, the design code of the slab thickness is deduced by the technique which is equivalent to the derivation of the RC standard, and the effect on the effective span by the size of the hole is examined.

Published

2002

41. Stresses in a Thick Plate Containing an Oblate Spheroidal Inclusion Under Axisymmetric Bending

Subjects

Inclusion, Stress Concentration, Thick Plate, Micromechanics, Oblate Spheroidal Inclusion, Elasticity

Abstract

The paper presents an axisymmetric solution for the stresses and displaements in an elastic thick plate containing an oblate spheroidal inclusion under axisymmetric bending around the z axis. The related spherical cavity and inclusion problems were solved by Tsuchida et al. in 1975. by using Papcovich-Neuber displacement potentials. We extended the method to spheroidal inclusion problem.

Published

2002

42. 偏平回転だ円体状介在物を有する厚板の曲げ

Subjects

Physics::Fluid Dynamics, Inclusion, Stress Concentration, Thick Plate, Micromechanics, Oblate Spheroidal Inclusion, Elasticity

Abstract

In the previous paper, we presented an axisymmetric solution for the stresses and displacements in an elastic thick plate containing an oblate spheroidal inclusion under axisymmetric bending around the z axis normal to the surface of the thick plate. In the present paper, we studied an asymmetric solution for an elastic thick plate containing an oblate spheroidal inclusion under transverse bending. Numerical results are given for different values of size, aspect ratio and stiffness ratio. The stress distributions around inclusion are shown graphically, and are compared with the axisymmetric results.

Published

2002

43. Strain rate concentration factor in comparison with stress concentration factor of a circumferential notch in a round bar specimen

Subjects

Notch, Tensile properties, Impact strength, Stress concentration, Strain rate

Abstract

High-speed tensile testing is now being recognized as a standard testing method for evaluating the impact strength of engineering materials. The impact speeds of Izod and Charpy tests cannot be controlled and therefore do not correspond to the real failure of real products. The brittle-ductile transition of structural materials is affected by the temperature and loading speed. In the high-speed tensile test, it is necessary to obtain the strain rate at the notch root accurately to understand the effect of impact load. For smooth specimens, the strain rate can be determined from the tensile speed u/t and specimen length l as εsmooth = u/tl. For notched specimens, however, the strain rate at the notch root εnotch should be analyzed accurately. In this study, therefore, the strain rate concentration factor defined as Ktε = εnotch/εsmooth is studied with varying the notch geometry. To predict the strain rate concentration factor Ktε accurately, the relationship between Ktε and the stress concentration factor Kt* = σmax/σgross is investigated. Here, σgross is the remote tensile stress and P is the tensile load. It is found that the strain concentration factor Ktε can be estimeted from stress concentration factor Kt* when the relative notch depth 2t/D≦0.5 (t : notch depth, D : the specimen diameter).

Published

2017

44. Convenient Stress Concentration Formula Useful for Any Shape of Fillet : Tension of a Stepped Round Bar with Fillet

Subjects

Test Specimen, Stress Concentration, Numerical Analysis, Tension, Elasticity, Body Force Method, Fillet

Abstract

In this work, stress concentration factors (SCFs) of a round bar with fillet K_t are considered on he basis of exact solutions now available for special cases and accurate numerical results. First, for he limiting cases of large and small values of the step including fillets, the body force method is used to calculate the SCFs ; then the formulas are obtained as K_ and K_. Here, K_ is a SCF of a deep shoulder fillet and K_ is a SCF of a shoulder fillet in semi-infinite plate. On the one hand, upon comparison of K_t and K_, it is found that K_t is nearly equal to K_ if the step is large or the radius of the fillet is small. On the other hand, if the step is small or the radius of the fillet is large, K_t is mainly controlled by K_ and the relative step length. The fillet shape is classified into several groups according as the fillet radius and the step length ; then, the least squares method is applied for calculation of K_t/K_ and K_t/K_. Finally, a set of convenient formulas useful for any shape of fillet in a round test specimen are proposed. The formulas yield SCFs for any shape of notch with less than 1% error in most cases.

Published

2001

45. Convenient Stress Concentration Formula Useful for Any Shape of Notch in a Flat Test Specimen : In-Plane Bending of a Flat Bar Having Circular-Arc Notches and V-shaped Notches

Subjects

Stress Concentration, Numerical Analysis, Notch, In-Plane Bending, Flat Test Specimen, Elasticity, Body Force Method

Abstract

In this work, stress concentration factors (SCFs) K_t of a flat bar with double circular-arc notches or double V-shaped notches are considered on the basis of exact solutions now available for special cases and accurate numerical results. First, for the limitting cases of deep and shallow notches, the body force method is used to calculate the SCFs ; then the formulas are obtained as K_ and K_. On the one hand, upon comparison of K_t and K_, it is found that K_t is nearly equal to K_ if the notch is deep or blunt. On the other hand, if the notch is sharp or shallow, K_t is mainly controlled by K_ and the notch depth. The notch shape is classified into several groups according as the notch radius and depth ; then, the least squares method is applied for calculation of K_t/K_ and K_t/K_. Finally, a set of convenient formulas useful for any shape of notch in a flat test specimen are proposed. The formulas yield SCFs With less than 1% error for any shape of notch.

Published

2001

46. Crystal Plasticity Analysis of the Disclination Type Deformation Field and Stress Concentration in a HCP Bicrystal

Subjects

Stress Concentration, Polycrystals, Dislocations, Grain Boundary Junctions, Ductility

Abstract

Plastic slip deformation of a HCP bicrystal is analyzed by a crystal plasticity FE code and distribution of plastic shear strain on the primary and secondary slip systems, as well as some stress components are examined. The constituent crystal are idealized ones and slip deformation on basal, prismatic and pyramidal slip systems can take place, but twin deformation cannot. After a deformation of 1% nominal tensile strain, sharp stress concentrations are developed at the junctions of the grain boundary plane and specimen surfaces even though the crystal orientations of the two grains differ only a few degree. Results are compared with the case for FCC bicrystals and effects of the activation of secondary slip systems are discussed., 本文データは学協会の許諾に基づきCiNiiから複製したものである

Published

2010

47. Convenient Stress Concentration Formula Useful for Any Shape of Notch in a Flat Test Specimen : (Tension of a Flat Bar Having Blunt Circular-Arc Notches or Sharp V-Shaped Notches

Subjects

Stress Concentration, Numerical Analysis, Notch, Tension, Flat Test Specimen, Body Force Metho, Elasticity

Abstract

In this work, stress concentration factors (SCFs) K_t of a flat bar with double circular-arc notches or double V-shaped notches are considered on the basis of exact solutions new available for special cases and accurate numerical results. First, for the limitting cases of deep and shallow notches, the body force method is used to calculate the SCFs;then the formulas are obtained as K_ and K_. On the one hand, upon comparison of K_t and K_ it is found that K_t is nearly equal to K_ if the notch is deep or blunt. On the other hand, if the notch is sharp or shallow, K_t is mainly controlled by K_ and the notch depth. The notch shape is classified into several groups according to the notch radius and depth;then, the least squares method is applied for calculation of K_t/K_ and K_t/K_. Finally, a set of convenient formulas useful for any shape of notch in a flat test specimen are proposed. The formulas yield SCFs with less than 1% error for any shape of notch.

Published

2000

48. Analysis of Interaction between Elliptical and Ellipsoidal Inclusions under Bending

Subjects

Numerical Analysis, Stress Concentration, Elliptical and Ellipsoidal Inclusions, Singular Integral Equations, Elasticity, Body Force Method

Abstract

This paper deals with interaction problems of elliptical and ellipsoidal inclusions under bending using singular integral equations of the body force method.These problems are formulated as a system of singular integral equations with Cauchy-type or logarithmic-type singularities, where unknown functions are densities of body forces distributed in the χ, y and r, θ, z directions in infinite bodies having the same elastic constants as those of the matrix and inclusions.In order to satisfy the boundary conditions along the elliptical and the ellipsoidal boundaries, the unknown functions are approximated by a linear combination of fundamental density functions and polynominals.The present method is found to yield the exact solutions for an elliptical and spherical inclusion under bending.Also , the present method yields rapidly converging numerical results for interface stresses in the interaction of inclusions.

Published

2000

49. A Consideration on the Fracture Criterion for a Sharp Notch

Subjects

Fracture Criterion, Stress Concentration, Notch, Fracture Mechanics, Stress Intensity Factor

Abstract

In this paper, a method of evaluating the static strength of a V-shaped notch based on the singular stress field at the notch tip is studied. The singular stress field is defined by two parameters, K_ and K_, which correspond to the intensities of the symmetric stress field and the skewsymmetric field, respectively. Four kinds of fracture criteria are considered ; two of them are based on the tensile strength δ_B and the other two are based on the fracture toughness K_. The usefullness of the criteria is investigated through the experiment results carried out on plane speciments of acrylic resin having a sharp notch for various notch configurations such as the opening angle, the inclined angle and the notch depth.

Published

1998

50. Convenient Stress Concentration Formula Useful for Any Shape of Notch in a Round Test Specimen: Rotating Bending Specimen Having an Extremely Sharp V-Shaped Notch or an Extremely Blunt Circular-Arc Notch

Subjects

Test Specimen, Stress Concentration, Numerical Analysis, Notch, Bending, Elasticity, Body Force Method

Abstract

In this work, stress concentration factors (SCFs) of a round bar with a circular-arc or V-shaped notch K_t are considered on the basis of exact solutions for special cases and accurate numerical results. First, for the limitting cases of deep and shallow notches, the body force method is used to calculate the SCFs ; then the formulas are obtained as K_ and K_. On the one hand, upon comparison of K_t and K_, it is found that K_t is nearly equal to K_ if the notch is deep or blunt. On the other hand, if the notch is sharp or shallow, K_t is mainly controlled by K_ and the notch depth. The notch shape is classified into several groups according to the notch radius and depth ; then, the least squares method is applied for calculation of K_t/K_ and K_t/K_. Finally, a set of convenient formulas useful for any shape of notch in a round test specimen are proposed. The formulas yield SCFs with less than 1% error for any shape of notch.

Published

1998