Your search keyword '"Thermal stresses -- Research"' showing total 107 results

1. The Flattening and Stiffening Effect of Centrifugal Stress on Circular Saw Blades in Different States

Author

Li, Bo and An, Yuan

Subjects

Thermal stresses -- Research, Materials research, Business, Forest products industry

Abstract

Circular saw blades have many states, before and during the sawing process, depending on the different residual stresses and flatness of the circular saw blades. Based on the different states of circular saw blades, the effect of rotating centrifugal stress on the dynamic stability of circular saw blades is different, mainly reflected in flattening and stiffening effects. In this article, three representative states of circular saw blades were chosen and studied. The finite element method was chosen to simulate the deformation behavior of circular saw blades in the three states. The flattening and stiffening effects of centrifugal stress on circular saw blades in the three states were systematically studied. The axial stiffness of the outer edge of circular saw blades is increased with rotating speed. The rotating speed has a flattening effect on the circular saw blade, as a result of a centrifugal stress field. When the circular saw blade is in a different state, there are some differences in the flattening and stiffening effect of centrifugal stress., The circular saw blade, an important production tool, is used to cut metal, stone, and wood. The sawing process is efficient and saves material. The dynamic stability of circular saw [...]

Published

2022

2. Numerical simulation of one-way concrete slabs reinforced with glass fiber reinforced polymer bars under service temperatures

Author

Lardjane, Samia, Bellakehal, Hizia, Zaidi, Ali, and Masmoudi, Radhouane

Subjects

Thermal stresses -- Research, Fiber reinforced concrete -- Research, Materials research, Engineering and manufacturing industries

Abstract

The thermal incompatibility between fiber reinforced polymer (FRP) bars and concrete may cause splitting cracks within the concrete and, eventually, the deterioration of the bond between the FRP bar and the concrete. This paper presents a numerical study using ADINA finite elements software to investigate the thermal behavior of actual one-way concrete slabs reinforced with glass FRP (GFRP) bars varying the ratio of concrete cover thickness to FRP bar diameter (c/[d.sub.b]) from 1.3 to 2.8. Slabs are submitted to temperature variations varied from -50 to 60[degrees]C. The main results prove that first radial cracks occur in concrete, at the FRP bar--concrete interface, at thermal loads ([DELTA][T.sub.cr]) varied between 15[degrees]C and 30[degrees]C. While, the circumferential cracks appear within concrete, at FRP bar--concrete interface, at [DELTA][T.sub.cr] varied between -15[degrees]C and - 35[degrees]C depending of the ratio c/[d.sub.b] (1.3 to 2.8) and the tensile strength of concrete [f.sub.ct] (1.9 to 2.9 MPa). These numerical thermal loading values are relatively in good agreement with those predicted from the analytical model. The numerical model shows that there is no failure of the concrete cover for low temperatures for slabs having c/[d.sub.b] = 1.3 to 2.8 and [f.sub.ct] = 1.9 to 2.9 MPa. Nevertheless, for high temperatures, the splitting failure of concrete cover is produced at thermal loads [DELTA][T.sub.sp]' varied from 30[degrees]C to 59[degrees]C. While, for concrete situated between GFRP bars, the splitting failure occurred at thermal loads [DELTA][T.sub.sp]' equal to 46[degrees]C. Thermal stresses and strains, and also cracking thermal loads predicted from the numerical model are compared with those obtained from analytical models and experimental tests. Key words: glass fiber reinforced polymer (GFRP) bars, concrete slabs, numerical model, cracking thermal loads, thermal stresses and strains. L'incompatibilite thermique entre les barres de polymere renforce de fibres (<< FRP >>) et le beton peut causer des fissurations dans le beton et, finalement, la deterioration du lien entre la barre de FRP et le beton. Dans le cadre de cet article, on presente une etude numerique qui utilise le logiciel d'elements finis ADINA afin d'examiner le comportement thermique de dalles unidirectionnelles en beton renforce de barres de FRP de verre (<>) en variant le rapport entre l'epaisseur d'enrobage et le diametre de barre de FRP (c/[d.sub.b]) de 1,3 a 2,8. Les dalles sont soumises a des variations de temperature entre -50 et 60[degrees]C. Les principaux resultats prouvent que les premieres fissures radiales se produisent dans le beton, a l'interface barre de FRP/beton, aux charges thermiques ([DELTA][T.sub.cr]) variant entre 15 et 30[degrees]C. Tandis que, les fissures circulaires apparaissent dans le beton, a l'interface barre de FRP/beton, a [DELTA][T.sub.cr] variant entre -15 et -35[degrees]C en fonction du rapport c/[d.sub.b] (1,3 a 2,8) et de la resistance a la traction du beton [f.sub.ct] (1,9 a 2,9 MPa). Ces valeurs numeriques de chargement thermique concordent relativement bien avec celles prevues par le modele analytique. Le modele numerique montre qu'il n'y a aucune defaillance de l'enrobage a de basses temperatures pour des dalles ayant c/[d.sub.b] = 1,3 a 2,8 et [f.sub.ct] = 1,9 a 2,9 MPa. Neanmoins, a des temperatures elevees, la defaillance par fissuration de l'enrobage s'est produite a des charges thermiques [DELTA][T.sub.sp]' variant de 30 a 59[degrees]C. Tandis que, pour le beton se trouvant entre les barres de GFRP, la defaillance par fissuration s'est produite a des charges thermiques [DELTA][T.sub.sp]' egalent a 46[degrees]C. Les contraintes et les deformations thermiques et aussi les charges thermiques de fissuration prevues au moyen du modele numerique sont comparees a celles obtenues au moyen des modeles analytiques et des essais experimentaux. [Traduit par la Redaction] Mots-cles : barres en polymere renforce de fibres de verre (GFRP), dalles de beton, modele numerique, charges thermiques de fissuration, contraintes et deformations thermiques., 1. Introduction Corrosion is the term used to describe the deterioration of a material as it reacts with its environment and is a natural process that occurs when materials such [...]

Published

2018

3. Thermoelastic response of a one-dimensional semi-infinite rod heated by a moving laser pulse

Author

Sun, Yuxin, Ma, Jingxuan, Wang, Xin, Soh, Ai Kah, and Yang, Jialing

Subjects

Thermal stresses -- Research, Elasticity -- Research, Physics

Abstract

In the present study, thermoelastic behavior of a semi-infinite rod, which is subjected to a time exponentially decaying laser pulse, is formulated. The rod is free at the left end and the laser pulse moves along the axial direction from the left end. The non-Fourier effect of the heat conduction equation is considered and the Laplace transformation method is employed in solving the governing equations. The temperature, displacement, strain, and stress in the rod are derived and the distributions of the parameters at different positions are analyzed. Also the influence of the laser speed is investigated. Key words: movable heat source, laser pulse, thermoelastic response, semi-infinite rod, non-Fourier effect. Nous presentons ici une formulation pour etudier le comportement thermo-elastique d'une tige semi-infinie soumise a une impulsion laser a decroissance exponentielle dans le temps. L'extremite gauche de la tige est fixee et l'impulsion se deplace axialement de la gauche vers la droite. Nous considerons l'equation de conduction non Fourier de la chaleur et nous utilisons la transformation de Laplace pour resoudre les equations directrices. Nous obtenons la temperature, le deplacement, l'effort et la deformation dans la tige et nous analysons la distribution des parametres a differentes positions. Nous regardons aussi l'influence de la vitesse du laser. [Traduit par la Redaction] Mots-cles : source de chaleur deplacable, impulsion laser, reponse thermoplastique, tige semi-infinie, effet non Fourier., 1. Introduction Boeing Company has developed a kind of high-energy laser weapon, which have successfully destroyed more than 150 target drones in three series of tests. This technology can be [...]

Published

2016

4. Tri-(butanediol-monobutyrate) citrate plasticizing poly(lactic acid): synthesis, crystallization, thermal, and mechanical properties

Author

Wan, Tong, Yang, Guangrui, and Du, Tao

Subjects

Crystallization -- Research, Plasticizers -- Properties -- Production processes, Lactic acid -- Properties -- Production processes, Thermal stresses -- Research, Chemical engineering -- Research, Chemical engineering research, Chemical synthesis -- Methods, Engineering and manufacturing industries, Science and technology

Abstract

Tri-(butanediol-monobutyrate) citrate (TBBC) as a new plasticizer for poly(lactic acid) (PLA) was synthesized via a two-step esterification. The chemical structure of TBBC was characterized by ¹H-nuclear magnetic resonance. The studies on solubility parameters, transparence, and storage stability indicated the good miscibility between PLA and TBBC. The glass transition, crystallization, thermal, and mechanical properties of PLA plasticized by TBBC were evaluated. With an increase in TBBC content, the glass transition temperature ([T.sub.g]), melting point ([T.sub.m]), and the cold crystallization temperature ([T.sub.cc]) of plasticized PLA gradually shifted to a lower temperature. The elongation at break and flexibility were greatly improved by the addition of TBBC. After 30 days of storage, PLA plasticized with up to 20 wt% of TBBC exhibited good storage stability and remained the original transparence and mechanical properties. The flexibility of PLA/TBBC films can be tuned by changing TBBC content. The corresponding crystalline morphology and structure were investigated by Polarizing optical microscope and X-ray diffraction as well. This study revealed that TBBC was miscible with PLA and may therefore be a promising plasticizer for PLA-based packaging materials. POLYM. ENG. SCI., 55:205-213, 2015. [C] 2014 Society of Plastics Engineers, INTRODUCTION The environmental and food safety problems have aroused people's concern about biodegradable materials [1]. Biodegradable polymers are considered as food packaging materials to solve serious ecological problems caused by [...]

Published

2015

5. Evolution and investigation of copper and gold ball bonds in extended reliability stressing

Author

Gan, C.L., Classe, F.C., Chan, B.L., and Hashim, U.

Subjects

Copper -- Properties, Thermal stresses -- Research, Reliability (Engineering) -- Research, Materials research, Gold -- Properties, Chemical bonds -- Research, Metals, metalworking and machinery industries

Abstract

This paper discusses the microstructure evolution of copper (Cu) and gold (Au) ball bonds after various extended reliability stresses such as biased highly accelerated temperature and humidity test (HAST), unbiased highly accelerated temperature and humidity test (UHAST), temperature cycling (TC), and high temperature storage life (HTSL) in BGA package. Objective of this study is to study the microstructure evolution and changes after long hours and long cycles of component reliability stressing and its predicted failure mechanisms and to determine the long-term reliability comparison with combination of bonding wires in HAST, UHAST, and TC. Secondary electron microscopy (SEM) and energy dispersive X-ray (EDX) have been carried out to understand the respective microstructure of failed samples in HAST, UHAST, TC, and HTSL long-term reliability failures. Respective failure mechanisms of copper and gold ball bonds carrion under HAST and UHAST, ball bond lifting in TC and HTSL have been analyzed and proposed. The evolution of surface morphology, including copper and gold ball bond micro cracking, gold ball bond Kirkendall microvoiding and intermetallic compound (IMC) formation, was studied in FBGA package with copper and gold ball bonds during various reliability stresses. Biased HAST, UHAST, TC, and HTSL mechanisms were proposed to explain the observed morphological changes and the resulting ball bond wear out modes after extended reliability stresses. Weibull reliability analyses have been established to compare the performance of copper and gold ball bonds under humid and dry environmental tests. Keywords Microstructure evolution * Copper and gold ball bonds * Failure mechanisms * SEM * EDX analysis * Extended reliability * Weibull plot, Introduction Gold and copper wire bondings are two most common bonding techniques used in microelectronic packaging in semiconductor industry. Recently, copper wire bonding appears to be the alternate materials and [...]

Published

2014

6. Thermoelastic damping of the axisymmetric vibration of laminated trilayered circular plate resonators

Author

Sun, Yuxin, Jiang, Yan, and Yang, Jialing

Subjects

Resonators -- Properties, Engineering research, Thermal stresses -- Research, Vibration control -- Methods, Physics

Abstract

Thermoelastic damping is a critical loss mechanism in micromachined resonators used for sensing and communication applications. In this paper, thermoelastic damping of the axisymmetric vibration of laminated circular plate resonators will be discussed. Based on the classical laminated plate theory assumptions, the governing equations of coupled thermoelastic problems are established for axisymmetric out-of-plane vibration of trilayered circular plate with fully clamped boundary conditions. The analytical expression for thermoelastic damping is obtained and the accuracy is verified through comparison with FEM results. Then the effect of material selection and the volume fraction of the covering layers are numerically evaluated. Finally, the thermoelastic damping for different vibration modes is also evaluated. PACS Nos.: 07.20.Dt, 46.25.Hf, 62.20.D-, 81.40.Jj, 65.40.De. L'amortissement thermo-elastique est un mecanisme critique de perte dans les resonateurs micro-usines utilises dans les applications de senseur et de communication. Nous etudions ici l'amortissement thermo-elastique des vibrations de symetrie axiale dans des resonateurs lamines circulaires. Sur la base de la theorie classique des plaques laminees, nous obtenons les equations directrices des problemes thermo-elastiques couples pour des vibrations a symetrie axiale hors plan de plaques circulaires tri-couches avec des conditions limites encastrees. Nous obtenons une expression analytique pour l'amortissement thermo-elastique et en verifions la precision en comparant les resultats avec ceux de FEM. Nous evaluons alors numeriquement l'effet du materiau selectionne et la fraction en volume des couches de recouvrement. Nous evaluons finalement l'amortissement thermo-elastique pour differents modes de vibration. [Traduit par la Redaction], 1. Introduction Miniaturized resonators are widely used as sensors and modulators in micro- and nanoelectromechanical systems [1-4]. For resonators, it is desired to design and construct systems with as little [...]

Published

2014

7. The effect of rotation on the problem of fiber-reinforced under generalized magnetothermoelasticity subject to thermal loading due to laser pulse: a comparison of different theories

Author

Othman, Mohamed I.A., Hasona, W.M., and Abd-Elaziz, Elsayed M.

Subjects

Rotational motion -- Research, Thermal stresses -- Research, Materials research, Fibrous composites -- Magnetic properties -- Thermal properties -- Mechanical properties, Magnetic fields -- Research, Physics

Abstract

In the present paper, we introduce the coupled theory, Lord-Schulman theory, and Green-Lindsay theory to study the influences of a magnetic field and rotation on a two-dimensional problem of fiber-reinforced thermoelasticity subject to thermal loading by a laser pulse. The material is a homogeneous isotropic elastic half-space and is heated by a non-Gaussian laser beam with pulse duration of 8 ps. The method applied here is to use normal mode analysis to solve a thermal shock problem. Deformation of a body depends on the nature of the force applied as well as the type of boundary conditions. Numerical results for the temperature, displacement, and thermal stress components are given and illustrated graphically in the absence and the presence of the magnetic field, rotation, reinforcement, and for two different values of time. PACS Nos.: 81.05.Ni, 46.25.Hf, 62.20.D-, 81.40.Jj. Nous introduisons ici la theorie couplee, celle de Lord-Shulman et celle Green-Lindsay pour etudier l'influence d'un champ magnetique et de la rotation sur un probleme bidimensionnel de thermoelasticite d'un milieu renforce par fibres sujet a une charge thermique due a un laser pulse. Le materiau, un demi-espace elastique, isotrope et homogene, est chauffe par un faisceau laser non gaussien dont les impulsions durent 8 ps. Nous appliquons ici une methode de modes normaux pour resoudre le probleme de chocs thermiques. La deformation du milieu depend de la nature des forces appliquees et des conditions limites. Nous presentons nos resultats numeriques et les illustrons graphiquement pour la temperature, le deplacement et les composantes des efforts thermiques, avec et sans champ magnetique, rotation, renforcement et pour deux differentes valeurs du temps. [Traduit par la Redaction], 1. Introduction The linear theory of elasticity is of paramount importance in the stress analysis of steel, which is the commonest engineering structural material. To a lesser extent, linear elasticity [...]

Published

2014

8. Improved tensile strength and thermal stability of thermoplastic carbon fiber fabric composites by heat induced crystallization of in situ polymerizable cyclic butylene terephthalate oligomers

Author

Kim, Sung Ho, Noh, Ye Ji, Ko, Young Woung, Kim, Seong Yun, and Youn, Jae Ryoun

Subjects

Crystallization -- Research, Oligomers -- Usage, Thermal stresses -- Research, Thermoplastics -- Mechanical properties -- Thermal properties -- Production processes, Materials research, Engineering and manufacturing industries, Science and technology

Abstract

Thermoplastic carbon fiber fabric reinforced composites (CFFRCs) were prepared using a novel fast manufacturing process with a low viscosity polymerizable cyclic butylene terephthalate (CBT) resin. Structure and properties of the composites altered by thermal annealing were investigated to develop appropriate post processing of the CFFRCs for fast production and lowering the processing cost. Annealing at 200°C for 120 min resulted in improved mechanical properties and thermal stability of the polymerized CBT (pCBT) based on differential scanning calorimetry, wide-angle X-ray diffraction, and thermo gravimetric analysis. The tensile strength of the CFFRC compression molded at 250°C for 2 min was 440 MPa and that of the CFFRC annealed at 200°C for 120 min after compression molding was 500 MPa, which is an improvement of 550 and 625% relative to the pCBT matrix, respectively. In addition, the thermal stability of the CFFRC annealed at 250°C for 120 min improved by 10°C. Therefore, tensile strength and thermal stability of the manufactured CFFRC can be improved by using the appropriate annealing conditions., INTRODUCTION Worldwide interest in energy reduction is increasing because of global issues, such as global warming, carbon emission, and inflation of oil prices, and weight savings in automobiles represent one [...]

Published

2014

9. Nanocomposites of silica reinforced polypropylene: correlation between morphology and properties

Author

Bouaziz, Amira, Jaziri, Mohamed, Dalmas, Florent, and Massardier, Valerie

Subjects

Polypropylene -- Production processes -- Mechanical properties -- Thermal properties, Thermal stresses -- Research, Reinforced plastics -- Production processes -- Mechanical properties -- Thermal properties, Materials research, Silica -- Usage, Plastics -- Extrusion, Engineering and manufacturing industries, Science and technology

Abstract

Polypropylene/fumed hydrophilic silica nanocomposites were prepared via melt mixing method using a single-screw extruder. Comparative study with and without compatibilizing copolymer agent (maleic anhydride grafted polypropylene: PP-g-AM) was conducted. The obtained results were interpreted in terms of silica nanoparticle-silica nanoparticle and silica nanoparticle-polymer interactions. These results have shown that the addition of nanofillers improves the properties of the nanocomposites. From transmission electron microscopy, it was found that agglomerations of silica particles into the PP matrix increased in average size with increasing silica contents, except in presence of the copolymer. Storage modulus values of the nanocomposites measured by dynamic mechanical thermal analysis were sensitive to the microstructure of the nanocomposites. Higher silica contents resulted in higher storage modulus, revealing that the material became stiffer. By adding the compatibilizer, a further increase of storage modulus was observed due to the finer dispersion of the filler in the matrix and the increased interfacial adhesion. Crystallization rates were found to increase with the increase of silica nanoparticles as well as PP-gMA content. In addition, silica nanoparticles and the compatibilizing agent present centers of germination and nucleation of crystallites. Thus, the use of the coupling agent resulted in a further enhancement of mechanical properties of the nanocomposites due to the reduction of silica agglomeration., INTRODUCTION Over the past decades, there has been a notable progress in the science and technology of polymer nanocomposites. This innovative class of materials made up of organic polymer composites [...]

Published

2014

10. Behaviour of H-piles supporting an integral abutment bridge

Author

Huntley, Shelley A. and Valsangkar, Arun J.

Subjects

Engineering research, Thermal stresses -- Research, Soil mechanics -- Research, Bridges -- Mechanical properties -- Thermal properties, Piling (Civil engineering) -- Mechanical properties -- Thermal properties, Earth sciences

Abstract

Integral abutment bridges accommodate thermal superstructure movements through flexible foundations rather than expansion joints. While these structures are a common alternative to conventional design, the literature on measured field stresses in piles supporting integral abutments appears to be quite limited. Therefore, field data from strain gauges installed on the abutment foundation piles of a 76 m long; two-span integral abutment bridge are the focus of this paper. Axial load, weak- and strong-axis bending moments of the foundation piles, as well as abutment movement and backfill response, are presented and discussed. Results indicate that the abutment foundation piles are bending in double curvature about the weak axis, as a result of thermal bridge movements, and bending also about the strong axis due to tilting of the abutments. A simple subgrade modulus approach is used to show its applicability in predicting behaviour under lateral loading. In the past, much emphasis has been placed on the lateral displacements of piles and less on variations of axial load. In this paper, a new hypothesis, which offers insight into the mechanisms behind the observed thermal variations in axial load, is proposed and assessed. The data from the field monitoring are also compared with the limited data reported in the literature. Key words: field monitoring, integral abutment bridge, axial load, pile moment, pile stress. Les culees de ponts integrales permettent les mouvements thermiques de la structure grace a des fondations flexibles plutot que par des joints d'expansion. Malgre que ces structures soient une alternative courante au concept conventionnel, la litterature sur les contraintes mesurees sur le terrain dans les pieux supportant les culees integrales semble limitee. C'est pourquoi cet article se penche sur des donnees de terrain de sondes de deformation installees sur des pieux de fondation-culee d'un pont a culee integrale de 76 m de long a deux voies. On presente et discute des charges axiales, des moments de torsion selon l'axe faible et fort des pieux de fondation, de meme que les mouvements de la culee et la reponse du remblai. Les resultats indiquent que les pieux de fondation-culee flechissent en courbure double selon l'axe faible en raison des mouvements thermiques du pont, et flechissent aussi selon l'axe fort en raison de l'inclinaison des culees. Une approche de module de sol simple est utilisee pour demontrer l'applicabilite de la prediction du comportement sous sollicitations laterales. Dans le passe, beaucoup d'emphase a ete mise sur les deplacements lateraux des pieux et moins sur les variations des charges axiales. Dans cet article, une nouvelle hypothese, qui offre des connaissances sur le mecanisme derriere les variations thermiques observees en chargement axial, est proposee et evaluee. Les donnees du suivi de terrain sont aussi comparees avec les donnees limitees disponibles dans la litterature. [Traduit par la Redaction] Mots-cles: suivi de terrain, culees de pont integrales, charge axiale, moment d'un pieu, contrainte d'un pieu., Introduction Thermal expansion and contraction of bridge structures has conventionally been accommodated through expansion joints. However, to ensure continued unrestricted movement of the superstructure, expansion joints require regular, and often [...]

Published

2014

11. Uniaxial time-dependent ratcheting behavior of bronze powder filled polytetrafluoroethylene at room and high temperature

Author

Xu, Wenjuan, Gao, Hong, Gao, Lilan, Ma, Jianhua, and Chen, Xu

Subjects

Bronze -- Mechanical properties -- Thermal properties, Polytetrafluoroethylene -- Thermal properties -- Mechanical properties, Thermal stresses -- Research, Materials research, Metal powders -- Mechanical properties -- Thermal properties, Metal powder products -- Mechanical properties -- Thermal properties, Engineering and manufacturing industries, Science and technology

Abstract

A series of tensile and ratcheting experiments for cold compaction polytetrafluoroethylene (PTFE) and bronze filled PTFE (PTFE/bronze) were conducted with Dynamic Mechanical Analyzer (DMA-Q800) at room and high temperature (473 K). The effects of peak stress-holding time, creep, recovery, mean stress history, stress-rate history, and pretension on the ratcheting behavior of PTFE/bronze were investigated. It is found that longer peak stress-holding time leads to larger ratcheting strain accumulation. In the meantime, the ratcheting strain accumulates more rapidly at high temperature and the influence of temperature is more obvious than that of the additive fraction of bronze. Creep strain produced during the uploading and the stress-holding time only partially recovers in the unloading process. Moreover, prior lower stress rate enhances the deformation resistance and restrains the ratcheting of subsequent cycling at higher stress rate. The ratcheting strain in the subsequent cyclic loading at lower mean stress is also restrained by previous cyclic loading at higher mean stress. Finally, the elastic modulus increases and the ratcheting strain is restrained apparently after the pretension. In addition, the elastic modulus and ratcheting strain of the PTFE/ bronze with both pretension and recovery are smaller than those with pretension but without recovery., INTRODUCTION Polytetrafluoroethylene (PTFE) as a widely used engineering material is a synthetic fluoropolymer of tetrafluoroethylene. Due to its low coefficient of friction, excellent dielectric properties and chemical inertness, PTFE is [...]

Published

2014

12. Preparation and properties of rice husk-filled plasticized wheat gluten biocomposites

Author

Emadi, Seyederfanhossein, Seki, Yoldas, Sever, Kutlay, and Sarikanat, Mehmet

Subjects

Gluten -- Properties, Thermal stresses -- Research, Materials research, Armature (Botany) -- Properties, Biopolymers -- Production processes -- Mechanical properties -- Thermal properties, Polymers -- Rheology, Engineering and manufacturing industries, Science and technology

Abstract

Rice husk (RH) reinforced wheat gluten/glycerol (Gly/ Glut) and rice husk (R) reinforced wheat gluten-glycerol/chitosan-polyethylene glycol (Gly/Glut-CP) biocomposites with varying rice husk loading were prepared. Morphological, thermal, and mechanical properties of the biocomposites were investigated by scanning electron microscope, thermogravimetric analyzer, and tensile testing machine, respectively. Water absorption properties and surface functional groups of the biocomposite films were determined by weight measurement and attentuated total reflectance Fourier transform infrared spectroscopy, respectively. The results were discussed in terms of chitosanpolyethylene glycol (CP) and rice husk content. Although CP and 1-g rice husk addition decreased maximum degradation temperature of Gly/Glut film, adding of more rice husk did not considerably change the maximum degradation temperature. As a result of adding CP, the tensile strength of Gly/Glut film was increased by about 183%, whereas tensile modulus was decreased by about 34%., INTRODUCTION The increasing demand for eco-friendly and biodegradability materials, the growing global environmental awareness and environmental concern, high rate of depletion of petroleum resources, increase in petroleum prices, and new [...]

Published

2014

13. Preparation and properties of TPU micro/nanofibers by a laser melt-electrospinning system

Author

Li, Xiuyan, Wang, Zhe, Wang, Jiaona, Liu, Jianli, and Li, Congju

Subjects

Crystallization -- Research, Nanoparticles -- Usage, Thermal stresses -- Research, Thermoplastics -- Usage, Polyurethanes -- Usage, Materials research, Polymeric composites -- Properties, Engineering and manufacturing industries, Science and technology

Abstract

Laser melt electrospinning is a novel technology to fabricate scaffolds in the tissue engineering applications. The melt electrospinning is much safer than the conventional solution electrospinning due to without solvent effect. In this study, thermoplastic polyurethane (TPU) micro/nanofibers were successfully prepared by using this method. The effects of laser current and applied voltage on the fibers morphologies were investigated by scanning electron microscopy. The thermal behaviors and crystallization conditions of the TPU under different states were demonstrated by differential scanning calorimetry and X-ray diffraction analysis. The mechanical property and the specific surface area of the TPU fibers membranes were also studied. All the analysis results showed that the effects of laser current and applied voltage on the average fiber diameter were complicated, the average fiber diameter ranging from 1.70 to 2.53 nm; the TPU is not an easily crystallized material; the electrospun fibers exhibited an amorphous phase; the average elongation at break laser of the electrospun TPU fiber membranes is about 134%; the average tensile strength is about 1.02 MPa and the specific surface area of the electrospun TPU fiber membrane is about 199 [m.sup.2]/g. POLYM. ENG. SCI., 54:1412-1417, 2014. © 2013 Society of Plastics Engineers, INTRODUCTION The polymer fibers have been applied in many areas such as high-performance filters, membranes optics, vascular grafts, protective clothing, molecular templates, tissue scaffolds, and sensing applications due to owning [...]

Published

2014

14. Dielectric, thermal, and swelling properties of calcium ion-crosslinked sodium alginate film

Author

Bekin, Seda, Sarmad, Shokat, Gurkan, Koray, Yenici, Gokcen, Keceli, Gonul, and Gurdag, Gulten

Subjects

Crosslinked polymers -- Research, Calcium ions -- Properties, Thermal stresses -- Research, Materials research, Dielectrics -- Properties, Engineering and manufacturing industries, Science and technology

Abstract

In this study, [Ca.sup.2+]-crosslinked sodium alginate (SA) gel films (SA-Ca/SA2-Ca) have been prepared, and their structural and thermal characterizations were investigated using fourier transform infrared spectroscopy, X-ray diffraction, differential scanning calorimetry, and thermogravimetric analysis, respectively. Dielectric characterization was performed at room temperature in the frequency range of 12 Hz-100 kHz. The equilibrium swelling value (ESV) of gel films was determined both in distilled water and in 0.1 M sodium chloride (NaCl) solution at room temperature. Sodium alginate films (SA/ SA2) were also prepared for use as reference. The effect of the crosslinking of sodium alginate on the dielectric and thermal properties of gel films was investigated by comparing the properties of gel films with those of SA/ SA2 films. Although ESV of [Ca.sup.2+]-crosslinked SA film in distilled water is about 350 [MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII] it decreased into one third in 0.1 M NaCl solution. The crosslinking of SA did not significantly affect the thermal properties, but it decreased the β-relaxation associated with the polar side groups. Frequency spectra of electric modulus, impedance and Cole-Cole plots confirmed the higher conductance values of SA-Ca films at low frequencies than those of SA film due to the presence of by-product of crosslinking., INTRODUCTION Sodium alginate (SA) is a low cost, environmentally safe, nontoxic, weak acidic, and an anionic, linear-chained natural polysaccharide. In recent years, it has gained more importance due to its [...]

Published

2014

15. Thermal, mechanical, and morphological characterization of biobased thermoplastic starch from agricultural waste/polypropylene blends

Author

Pang, Ming Meng, Pun, Meng Yan, and Ishak, Zainal Arifin Mohd.

Subjects

Polypropylene -- Mechanical properties -- Thermal properties, Thermoplastics -- Mechanical properties -- Thermal properties, Thermal stresses -- Research, Materials research, Agricultural wastes -- Mechanical properties -- Thermal properties, Polymers -- Rheology, Engineering and manufacturing industries, Science and technology

Abstract

The thermal, mechanical, and morphological properties of biobased thermoplastic starch (TPS) obtained from agricultural waste seed (AWS) and agricultural waste tuber (AWT) blended with polypropylene (PP) were investigated in this article. The grounded (pulverized) AWS and AWT were different in amylose/amylopectin ratios and contained relatively low starch content (≤ 50%). The commercial grade of TPS (CS) and native tapioca starch blended PP (NTS/PP) were also prepared for comparison. The performances of the TPS/ PP blends were dependent on the starch composition (e.g., amylose-to-amylopectin ratio), particle size, dispersion, and interfacial adhesion with matrix. The high-amylopectin starch blend (i.e., AWS/PP) was more susceptible to thermal degradation than the amylose-rich material (i.e., NTS/PP). The addition of starch to PP not only led to a stiffening effect (i.e., increase in storage modulus), but it also affected the relaxation of polymer matrix by shifting the thermal transition (i.e., glass transition temperature) to a higher temperature. POLYM., INTRODUCTION Biobased product is a product containing in whole or partly made from renewable resources according to definition in ASTM D6852. ASTM D6866 is the standard test method for biobased [...]

Published

2014

16. Mechanical and flame resistant properties of polycarbonate-carbon nanotubes-ochre composites

Author

Moon, Sung Cheal, Kim, Jeong Yeol, and Oh, Bong Taek

Subjects

Thermal stresses -- Research, Materials research, Polymeric composites -- Mechanical properties -- Thermal properties, Nanotubes -- Mechanical properties -- Thermal properties, Polycarbonates -- Mechanical properties -- Thermal properties, Engineering and manufacturing industries, Science and technology

Abstract

Ochre (Oc), with its high absorption and viscous properties and presence of several inorganic components, was incorporated in a polycarbonate-unmodified carbon nanotubes using processing methods such as electrospinning and compression molding, to produce strong and flame resistant composites with biaxially oriented nanomaterials. These composites were found to have good mechanical properties (ultimate tensile strength of ~95.3 MPa) and flame resistance (~464 J [g.sup.-1] [K.sup.-1] heat release capacity) when ~1 wt% of single-walled carbon nanotubes was used with 2.5 wt% Oc, which was used as a compatibilizer and flame retardant., INTRODUCTION Effective reinforcement of a polymer matrix requires resolution of two classic problems as follows: (1) the tendency of reinforcing agents to agglomerate uncontrollably in the matrix polymer and (2) [...]

Published

2014

17. Effect of ultrasonication and other processing conditions on the morphology, thermomechanical, and piezoelectric properties of poly(vinylidene difluoride-trifluoroethylene) copolymer films

Author

Nguyen, Van Son, Rouxel, Didier, Meier, Matthias, Vincent, Brice, Dahoun, Abdesselam, Thomas, Sabu, and Dos Santos, Fabrice Domingues

Subjects

Polyvinylidene fluoride -- Properties -- Production processes, Ultrasonic waves -- Usage, Chemical processes -- Research, Thermal stresses -- Research, Materials research, Piezoelectric materials -- Properties -- Production processes, Engineering and manufacturing industries, Science and technology

Abstract

This study is carried out on the effect of processing conditions including preparation methods, ultrasonication, film thickness, and thermal annealing on the thermal, mechanical, and piezoelectric properties of copolymer of poly(vinylidene difluoride-trifluoroethylene) (P(VDF-TrFE)J. Free-standing films and films on substrates are prepared by solvent casting and spincoating, respectively. The results obtained by differential scanning calorimetry show that the Curie transition of the copolymer films was influenced by the preparation methods, with very little difference in the melting transition. The difference was attributed to a less uniform distribution of TrFE comonomer units within the crystalline and amorphous regions of the spin-coating films. However, no effect of the preparation methods on the piezoelectric properties of the films was observed. It is also found that the short ultrasonication, film thickness higher than critical value of crystallization of P(VDF-TrFE) (about 100 nm), and drying before annealing did not have a significant effect on the properties of the films. Surprisingly, the ultrasonication had a clear impact on the relaxations at high temperature of the polymer chains. In addition, this study indicates that a short annealing by 10 min at 140°C was enough to obtain well-crystallized films, which is interesting from the industrial point of view., INTRODUCTION Since the discovery of its strong piezoelectric activity in 1969 by Kawai [1], poly(vinylidene fluoride) (PVDF) and its copolymers, in particular the copolymers of vinylidene difluoride and trifluoroethylene P(VDF-TrFE) [...]

Published

2014

18. The effect of initial stress on generalized thermoelastic medium with three-phase-lag model under temperature-dependent properties

Author

Othman, Mohamed I.A., Hasona, W.M., and Eraki, Ebtesam E.M.

Subjects

Engineering research, Thermal stresses -- Research, Elasticity -- Research, Physics

Abstract

The present paper attempts to investigate the propagation of plane waves in an isotropic elastic medium under the effect of initial stress and temperature-dependent properties. The modulus of elasticity is taken as a linear function of reference temperature. The formulation is applied under the thermoelasticity theory with three-phase-lag, proposed by Choudhuri (J. Thermal Stresses, 30, 231 (2007)). Normal mode analysis is used to obtain the expressions for the displacement components, the temperature, the stress, and the strain components. Numerical results for the field quantities are given in the physical domain and illustrated graphically. Comparisons are made with the results predicted by different theories (Lord-Shulman theory, the theory of thermoelasticity type III, and the three-phase-lag model) in the absence and presence of the initial stress as well as the case where the modulus of elasticity is independent of temperature. PACS Nos.: 46.25.Hf, 62.20.D-, 81.40.Jj. Nous etudions ici la propagation d'ondes planes dans un milieu elastique isotrope et leur dependance sur la charge initiale et les proprietes qui varient avec la temperature. Nous prenons pour acquis que le module d'elasticite est une fonction lineaire de la temperature de reference. Nous appliquons la theorie de la thermo-elasticite avec trois retards de phase, proposee par Choudhuri (J. Thermal Stresses, 30, 231 (2007)). L'analyse en modes normaux nous permet d'obtenir les expressions pour les composantes du deplacement, la temperature, la charge et les deformations. Nous presentons les resultats numeriques pour les champs dans le domaine physique et les illustrons graphiquement. Nous comparons ces resultats avec ceux d'autres theories (la theorie de Lord-Shulman, la theorie de la thermo-elasticite de type III et le modele a trois retards de phase), en presence et en absence de charge initiale, et lorsque le module d'elasticite est independant de la temperature., 1. Introduction Generalized theories of thermoelasticity have been developed to overcome the infinite propagation speed of thermal signals predicted by the classical coupled dynamical theory of thermoelasticity [1]. The subject [...]

Published

2014

19. Effect of the particle size of expandable graphite on the thermal stability, flammability, and mechanical properties of high-density polyethylene/ethylene vinyl-acetate/expandable graphite composites

Author

Sun, Zhidan, Ma, Yonghong, Xu, Yang, Chen, Xiaolang, Chen, Man, Yu, Jie, Hu, Shuchun, and Zhang, Zhibin

Subjects

Graphite -- Mechanical properties -- Thermal properties, Thermal stresses -- Research, Materials research, Polymeric composites -- Mechanical properties -- Thermal properties, Engineering and manufacturing industries, Science and technology

Abstract

In this article, high-density polyethylene/ethylene vinyl-acetate copolymer (HDPE/EVA) composites filled with two different particle sizes (45 and 150 µm) of expandable graphite (EG) were prepared by using a twin-screw extruder. The thermal stability, flammability, and mechanical properties of HDPE/EVA/EG composites were investigated by thermogravimetric analysis (TGA), cone calorimeter test (CCT), tensile test, and scanning electron microscopy (SEM). The results from TGA and CCT indicated that EG significantly enhanced the thermal stability and fire resistance of HDPE/EVA blend. The thermal stability and flame retardancy of HDPE/ EVA/EG composites were improved with decreasing particle size of EG. Although the onset of weight loss of the flame-retardant composites occurred at a lower temperature than that of HDPE/EVA blend, the flame-retardant composites produced a large amount of char residue at a high temperature. The consolidated char layer formed a barrier, which could reduce heat, low-molecular transfer, and air incursion, and thus enhanced the flame retardancy. The data from the tensile test showed that the addition of EG deteriorated the mechanical properties; however, the tensile stress and strain of HDPE/EVA/EG composites increased with decreasing the particle size of EG owing to the strong interface adhesion between polymer matrix and inorganic particles. POLYM. ENG. SCI., 54:1162-1169, 2014. © 2013 Society of Plastics Engineers, INTRODUCTION Polyethylene (PE) is one of the most widely used polymeric materials owing to its low cost, balanced mechanical properties, good processability, and so on [1-3]. However, there are some [...]

Published

2014

20. Systematic Organophilization of Montmorillonite: The Impact Thereof on the Rheometric and Mechanical Characteristics of NBR and SBR Based Nanocomposites

Author

Essawy, Hisham A., Tawfik, Magda E., Khalil, Ahmed M., and El-Sabbagh, Salwa H.

Subjects

Montmorillonite -- Mechanical properties -- Identification and classification -- Thermal properties, Styrene-butadiene rubber -- Mechanical properties -- Identification and classification -- Thermal properties, Thermal stresses -- Research, Materials research, Polymers -- Rheology, Engineering and manufacturing industries, Science and technology

Abstract

Different montmorillonites either, completely hydrophilic (Mont-O), amphiphilic (Mont-25, Mont-50, and Mont-75) or completely hydrophobic (Mont-100) were used as reinforcing fillers for styrene butadiene rubber (SBR) and acrylonitrile butadiene rubber (NBR) [...]

Published

2014

21. Morphology and Properties of Highly Filled iPP/[Ti0/sub.2] Nanocomposites

Author

Zohrevand, Ahmad, Ajji, Abdellah, and Frej, Mighri

Subjects

Titanium dioxide -- Mechanical properties -- Thermal properties, Polypropylene -- Mechanical properties -- Thermal properties, Thermal stresses -- Research, Materials research, Polymers -- Rheology, Polymeric composites -- Mechanical properties -- Thermal properties, Engineering and manufacturing industries, Science and technology

Abstract

Nanocomposites based on isotactic polypropylene (tPP) and titanium dioxide ([TiO.sub.2]) nanoparticle containing 1-15 vol% (4.6-45.5 wt%) of the nanoparticle were prepared by the melt blending process. The effect of an [...]

Published

2014

22. Curing, gelling, thermomechanical, and thermal decomposition behaviors of anhydride-cured epoxy (dgeba)/epoxidized soybean oil compositions

Subjects

Soy oil -- Properties, Thermal stresses -- Research, Curing -- Research, Epoxy resins -- Properties, Materials research, Decomposition (Chemistry) -- Research, Polymeric composites -- Properties, Engineering and manufacturing industries, Science and technology

Abstract

This work was aimed at studying the effects of incorporation of epoxidized soybean oil (ESO) in a standard bisphenol A-type epoxy resin (EP) cured by anhydride hardener. The EP ESO [...]

Published

2014

23. Curing behavior, thermal, and mechanical properties of epoxy resins cured with a novel liquid crystalline dicarboxylic acid curing agent

Author

Sinh, Le Hoang, Trung, Nguyen Ngoc, Son, Bui Thanh, Shin, Seunghan, Thanh, Dinh Tan, and Bae, Jin-Young

Subjects

Thermal stresses -- Research, Epoxy resins -- Thermal properties -- Mechanical properties -- Production processes, Materials research, Engineering and manufacturing industries, Science and technology

Abstract

A novel di-carboxyiic acid curing agent (DACA) was successfully synthesized and cured with three different epoxy resins: glycidyl end-capped poly(bisphenol-A-coepichlorohydrin) (pDGEBA, [M.sub.n] 377), N,N-diglycidyl-4-glycidyloxyaniline (TGAP), and 4,4'-methylenebis(N,N-diglycidylaniline) (TGDDM). The cured epoxy exhibited excellent thermal stability, which was indicated by high initial degradation temperature ([T.sub.id]) and char yield. The [T.sub.id] values of cured epoxy were in the range of 327-338°C, and the char yields increased with increasing epoxy functionality. The char yields of cured DACA/ pDGEPA, DACA/TGAP, and DACA/TGDDM samples were 21.1, 60.4, and 66.9%, respectively. In addition, the cured epoxy samples also showed low coefficients of thermal expansion and high storage moduli (E'), which were around 60 ppm/°C and 2800 MPa, respectively. The failure surfaces were ductile and rough, so the cured epoxy samples are expected to have high fracture toughness and impact strength. POLYM. ENG. SCI., 54:695-703, 2014. © 2013 Society of Plastics Engineers, INTRODUCTION Epoxy resins are a versatile group of thermoset polymers that have excellent properties, such as stiffness, strength, chemical resistance, low dielectric constant and loss, adhesiveness to substrates, and thermal [...]

Published

2014

24. Effect of rolling temperature on microstructure and tensile properties of polypropylene

Author

Murata, Takuya, Qiu, Jianhui, and Wu, Xueli

Subjects

Polypropylene -- Mechanical properties -- Thermal properties, Thermal stresses -- Research, Microstructure -- Research, Engineering and manufacturing industries, Science and technology

Abstract

Rolling process was carried out with extruded polypropylene as crystalline polymer at various rolling temperatures, and the rolling characteristics, cross-section morphologies, and tensile properties were investigated. The rolling characteristics were evaluated by springback and dimensional change. The springback increased with increasing rolling temperature. The increment of length was larger than that of width because of the influence of uniaxial drawing by rotation of the rollers. Uniform morphologies were observed at a rolling ratio of 70% and a rolling temperature of 23°C. In contrast, molecular orientation near the surface was higher compared with the inner part when rolled at 70°C. Furthermore, micro spherulitic structures were observed near the surface where recrystallization occurred because of the rising temperature on the specimen surface by friction. Therefore, different morphologies appeared near the surface and in the inner part. Tensile strength was obtained for the rolling direction when rolled at 110°C lower than at other rolling temperatures. It was likely that the molecular orientation was decreased by increasing the spring-back when rolled at high temperature. POLYM. ENG. SCI., 53:2573-2581, 2013. © 2013 Society of Plastics Engineers, INTRODUCTION It is widely known that morphologies such as crystalline structure, molecular orientation, and crystallinity influence mechanical properties. For example, the properties of polymer materials are enhanced by high molecular [...]

Published

2013

25. Morphological, mechanical, tribological, and thermal expansion properties of organoclay reinforced polyethylene composites

Author

Pollanen, Maija, Suihkonen, Reija, Nevalainen, Katja, Koistinen, Arto P., Suvanto, Mika, Vuorinen, Jyrki, and Pakkanen, Tuula T.

Subjects

Polyethylene -- Mechanical properties -- Thermal properties, Thermal stresses -- Research, Reinforced plastics -- Mechanical properties -- Thermal properties -- Composition, Tribology -- Research, Clay -- Mechanical properties -- Thermal properties, Engineering and manufacturing industries, Science and technology

Abstract

The morphological, mechanical, thermal, and tribological properties of high-density polyethylene (HDPE) composites reinforced with organo-modified nanoclay (3 and 6 wt%) were studied. A commercial maleic anhydride-based polymeric compatibilizer (PEgMA) was used to improve the adhesion between the polyethylene and clay. Transmission electron microscopy (TEM) characterization of composites revealed that nanoclay exists mainly in a multilayered structure in the HDPE matrix. Mechanical testing of composites showed that Young's modulus and tensile strength increased with nanoclay content. Coefficients of the linear thermal expansion (CLTE) of HDPE-PEgMA-clay composites were slightly lower in the flow direction than those of HDPE-PEgMA. The tribological properties were measured in dry conditions against a steel counterface. The friction coefficient of the matrix was decreased by the addition of clay. Electron microscopic results suggested that the wear mechanism for HDPE and HDPE composites was mainly adhesive. Clay agglomerates were observed on the worn surfaces of the composites, which may partly explain decreased friction. POLYM. ENG. SCI., 53: 1279-1286, 2013. © 2012 Society of Plastics Engineers, INTRODUCTION Polyethylene is a widely used semicrystalline polyolefin that possess a good chemical resistance, low cost, easy processability, and moderate mechanical properties (1). Traditionally, the properties of polymers have been [...]

Published

2013

26. Effect of heating and stretching polyacrylonitrile precursor fibers in steam on the properties of stabilized fibers and carbon fibers

Author

Qin, Xianying, Lu, Yonggen, Xiao, Hao, and Zhao, Weizhe

Subjects

Polyacrylonitrile -- Mechanical properties -- Thermal properties, Heating -- Research, Thermal stresses -- Research, Textile fibers, Synthetic -- Mechanical properties -- Thermal properties, Steam -- Properties, Engineering and manufacturing industries, Science and technology

Abstract

Polyacrylonitrile (PAN) fibers were heated and stretched in a steam bath mixed with nitrogen in the early stage of stabilization. During this process, the flexible linear chain of PAN molecule was converted to a rigid ladder structure by intramolecular cyclization. The shrinkage tension along the fiber axis decreased during this heat treatment, because water molecules here acted as a plasticizer for stretching. Consequently, the preferred orientation of ladder molecules in the stabilized fibers was enhanced. As a result, the preferred orientation, crystallite dimensions, and mechanical properties of the resultant carbon fibers (CFs) and graphite fibers (GFs) were improved, comparing with the corresponding CFs and GFs without pretreatment in the steam bath. POLYM. ENG. SCI., 53:827-832, 2013. © 2012 Society of Plastics Engineers, INTRODUCTION The preferred orientation of crystallites along the fiber axis is one of the most important structure parameters for carbon fibers (CFs). Higher preferred orientation usually gives rise to higher [...]

Published

2013

27. Effect of soil temperature changes on geogrid strains

Author

Zarnani, S., Scott, J.D., and Sego, D.C.

Subjects

Thermal stresses -- Research, Soils -- Thermal properties, Soil temperature -- Research, Earth sciences

Abstract

Temperatures were measured along instrumented geogrids to determine thermal strains and their changes with seasonal temperatures. It was observed that the application of temperature correction to the measured strain values by electrical wire resistance (EWR) strain gauges to compensate for temperature-induced strains is not correct. Because of the effects of soil confinement, the geogrids confined with soil do not undergo thermal expansion or contraction from temperature change if slippage between the soil and geogrid cannot occur. Instead of thermal strains, thermal stress or thermal force will be developed in the geogrids with the magnitude depending on the elastic properties, temperature change, and linear coefficient of thermal expansion. Key words: geogrid, strain gauge, temperature, thermocouple, thermal strain, thermal stress. Les temperatures ont ete mesurees le long de geogrilles instrumentees afin de determiner les deformations thermiques et leurs variations selon les variations saisonnieres des temperatures. Il a ete observe que l'application de la correction pour compenser les deformations induites par la temperature sur les mesures de deformations realisees avec des jauges de deformations par resistance du fil electrique (RFE) n'est pas correcte. En raison des effets de confinement du sol, les geogrilles confinees a l'interieur du sol ne subissent pas d'effets d'expansion ou de contraction thermique lorsque la temperature change s'il n'y a pas de glissement entre le sol et la geogrille. Plutot que des deformations thermiques, des contraintes ou forces thermiques seront developpees dans la geogrille, a des magnitudes dependant des proprietes elastiques, des variations de temperature et du coefficient lineaire d' expansion thermique. Mots-cles : geogrille, jauge de deformation, temperature, thermocouple, deformation thermique, contrainte thermique. [Traduit par la Redaction], Introduction The first author performed a research graduate thesis in 2003 on the long-term performance of a geogrid-reinforced test embankment constructed in 1986. Vertical and horizontal inclinometers and extensometers, settlement [...]

Published

2011

28. Closed-form solution of Cattaneo equation including volumetric source in relation to laser short-pulse heating

Author

Qahtani, H. Al- and Yilbas, B.S.

Subjects

Heat -- Conduction, Heating -- Research, Thermal stresses -- Research, Lasers -- Usage, Laser, Physics

Abstract

The wave nature of the heating model is considered, incorporating the Cattaneo equation with the presence of a volumetric heat source. The volumetric heat generation resembles the step input laser short-pulse intensity. The governing of the heat equation is solved analytically using the Laplace transformation method. The stress field generated due to thermal contraction and expansion of the substrate material is formulated and the closed-form solution is presented. It is found that the wave nature of the heating is dominant during the period of the irradiated short-pulse; however, in the late cooling period, the wave nature of heating is replaced by diffusional heat conduction, governed by Fourier's law. The stress field during the heating cycle is compressive and becomes tensile in the cooling cycle. PACS No: 44.10.+i Nous etudions la nature ondulatoire du modele de chauffage incorporant l'equation de Cattaneo, avec la presence de la source volumique de chaleur. La generation volumique de chaleur ressemble a intensite d'un laser a impulsion courte avec signal d'entree en echelon. Nous solutionnons analytiquement l'equation gouvernante de la chaleur en utilisant la methode de la transformation de Laplace. Le champ de contrainte genere par la contraction et l'expansion thermique du materiel du substrat est mis en formule et nous en presentons une solution analytique. Nous trouvons que le caractere ondulatoire du chauffage est dominant pendant la periode d' irradiation en impulsion courte, mais la conduction de chaleur de Fourier par diffusion domine la periode du refroidissement. Le champ de contrainte est en compression pendant le chauffage, mais en etirement pendant le refroidissement. [Traduit par la Redaction], 1. Introduction In short-pulse laser heating of metal surfaces, the absorption depth is small and the heating time is short. This results in a heat wave propagatiing at finite speed [...]

Published

2011

29. Turning up the heat: temperature influences the relative importance of top-down and bottom-up effects

Author

Hoekman, David

Subjects

Thermal stresses -- Research, Climate sensitivity -- Research, Habitat (Ecology) -- Modification, Habitat (Ecology) -- Research, Biological sciences, Environmental issues

Abstract

Understanding how communities respond to changes in temperature is a major challenge for community ecology. Temperature influences the relative degree to which top-down and bottom-up forces structure ecological communities. In greenhouse experiments using the aquatic community found in pitcher plants (Sarracenia purpurea), I tested how temperature affected the relative importance of top-down (mosquito predation) and bottom-up (ant carcasses) forces on protozoa and bacteria populations. While bottom-up effects did not vary consistently with temperature, the top-down effects of predators on protozoa increased at higher temperatures. These results suggest that temperature could change the relative importance of top-down and bottom-up effects in ecological communities. Specifically, higher temperature may increase the strength of top-down effects by raising predator metabolic rate and concomitant processes (e.g., activity, foraging, digestion, growth) relative to cooler temperatures. These findings apply broadly to an understanding of trophic interactions in a variable environment and are especially relevant in the context of ongoing climate change. Key words. food web; laboratory experiment; predation; temperature; top-down vs. bottom-up forces; Wyeomyia smithii.

Published

2010

30. Modeling and behavior of steel plate connections subject to various fire scenarios

Author

Garlock, Maria E. and Selamet, Serdar

Subjects

Plates, Iron and steel -- Mechanical properties, Plates, Iron and steel -- Thermal properties, Plates, Iron and steel -- Testing, Thermal stresses -- Research, Stress analysis (Engineering) -- Methods, Engineering and manufacturing industries, Science and technology

Abstract

Shear connections are common connection types and they are designed to resist only shear loads. In a fire event, the axial restraint provided by adjacent structure creates unanticipated compressive and tensile forces in the beam and thus the connection. Using finite-element models, this study examines single-plate shear connections that are bolted to the beam and welded to the supporting girder. A floor subassembly, which includes the beam, girder, slab, and connection, is modeled so that appropriate forces are applied to the connection. The model is validated with the experiments of bolted lap splice plates at elevated temperatures, as well as full-scale experiments. This paper (1) illustrates efficient modeling methods for these floor subassemblies; (2) evaluates the importance of the slab in the connection response; and (3) examines the effects of the rate of heating and cooling on the connection. The results show that care needs to be taken as to how the concrete slab is represented in the model. The heating and cooling rates affect the beam stress distribution, peak temperatures, and peak displacements, but not the peak beam axial force. Also, the cooling phase creates large tensile forces in the connection which can lead to failure. DOI: 10.1061/(ASCE)ST.1943-541X.0000179 CE Database subject headings: Finite element method; Contacts; Connections; Fites; Steel. Author keywords: Finite element; Contact; Connection; Fite; Steel.

Published

2010

31. Consequences of material addition for a beam strip in a thermal environment

Author

Haney, Mark A. and Grandhi, Ramana V.

Subjects

Thermal stresses -- Research, Expansion (Heat) -- Control, Aerospace and defense industries, Business

Abstract

Aircraft structure subjected to elevated temperature presents a challenging design environment as damaging thermal stress can result. Thermal stress in a structural component is typically alleviated by accommodating the thermal expansion. However, very little work has been done that directly addresses the situation where such a prescription for expansion is not possible. When a structural component is failing due to tensile stresses which are thermally induced, the answer to the question of how best to stiffen the structure in this environment is far from trivial. This work demonstrates that conventional stiffening techniques, for example, thickness increase, may actually increase the rate of damage, as well as generate additional load that must be reacted by sub- and surrounding structure. Because flat plates represent a common structural element that is susceptible to developing tensile stresses due to thermally induced out-of-plane deformation, a simple strip model which represents cylindrical bending in a semi-infinite flat plate is chosen as the focus of this work.

Published

2009

32. Consequences of heat hardening on a field fitness component in Drosophila depend on environmental temperature

Author

Loeschcke, Volker and Hoffmann, Ary A.

Subjects

Cost benefit analysis -- Research, Dispersal (Ecology) -- Research, Drosophila -- Research, Resource allocation -- Research, Thermal stresses -- Research, Cost benefit analysis, Biological sciences, Earth sciences

Published

2007

33. Aerothermodynamic aspects of railgun-assisted launches of projectiles with sub- and low-earth-orbit payloads

Author

Bozic, Ognjan and Giese, Peter

Subjects

Aerodynamics -- Research, Hypervelocity guns -- Research, Projectiles -- Research, Thermal stresses -- Research, Business, Electronics, Electronics and electrical industries

Abstract

A Railgun-concept for the launch of small payloads into low-Earth orbits is currently under investigation. The first major project milestone foresees a 32-MJ railgun system able to launch nonpropelled projectiles with experiments for high-atmospheric research to an altitude of 115 km. This will be followed by a system to launch single-stage rocket-propelled projectiles to put in orbit nanosatellites using a 3.4-GJ railgun with a length of 180 m. One of the main issues to be investigated is the extreme thermal conditions the projectile's surfaces are exposed to, namely high temperatures and high thermal loads. These are caused by friction and turbulent flow properties, when the projectile rushes through the dense Earth's atmosphere in less than 30 s. The important questions to be answered for the design of a hypersonic projectile are the determination of the duration, magnitude, and location of the maximum temperatures with respect to the projectile's surface and its corresponding internal structure. For the determination of the complicated physical conditions, a two-step approach is used. In a so-called predesign phase, the HF3T code of the DLR is applied to estimate time-dependent temperature changes on the projectile's surface and/or within the material's structure as a function of the trajectory parameters. Finally, the three-degree-of-freedom trajectory program TRAJECTORY 3D of DLR is used to generate a detailed time-dependent data set, which includes the values for projectile velocity, Mach and Reynolds numbers, and atmospheric properties as a function of altitude. This data set is exchangeable with the TAU code of DLR for the solution of the Navier--Stokes equations, enabling pseudo-unsteady flow solutions along the trajectory. The solutions resulting from both approaches are then compared with emphasis on the surface temperature distributions. This strategy allows the verification of the feasibility of the proposed design solution for the railgun launched hypersonic projectiles. Index Terms--Aerothermodynamics, coupled calculations, heat load, railgun, unsteady flow.

Published

2007

34. Cracking and dominant stresses in the throat region of c-shaped solid armatures

Author

Watt, T.J. and Bryant, M.D.

Subjects

Armatures -- Properties, Armatures -- Research, Thermal stresses -- Research, Business, Electronics, Electronics and electrical industries

Abstract

The throat region of solid armatures is subjected to significant stress and temperature during a railgun launch. Recovered aluminum alloy armatures show evidence of plastic deformation, melting, and even cracking in the throat region. Plastic deformation can result from magnetic pinch or thermal expansion forces and melting from ohmic heating. Although cracking is historically associated with grain boundary melting, the cracks observed in recently recovered armatures are likely a result of thermal stresses. Finite-element codes EMAP3D and DYNA3D were linked to assess stresses generated by magnetic forces, inertial loading, wear, and thermal expansions. For low-speed armatures, thermal stresses were found to be as important as magnetic stresses. The observed cracking is likely due to rapid cooling, similar to quench cracking, and may or may not occur during launch. Index Terms--Cracking, solid armatures, throat region.

Published

2007

35. Experiments with armature contact claddings

Author

Stefani, Francis, Crawford, Mark, Melton, David, and Watt, Trevor

Subjects

Armatures -- Research, Metal cladding -- Research, Thermal stresses -- Research, Titanium -- Research, Business, Electronics, Electronics and electrical industries

Abstract

This paper summarizes experiments to investigate the possibility of delaying the onset of transition by using armatures with high melting temperatures. The rationale for the experiments was that armature materials with high melting points might outperform aluminum by reducing melting and erosion at the rail--armature interface. The tests used a novel technique that consists of placing thin claddings on the rail-contacting surfaces of the armatures. Two low-speed tests with copper armature claddings proved that claddings affixed to the trailing arms can survive a railgun launch. These tests were followed by four tests at about 2 km/s that used titanium armature claddings. These tests showed that titanium-clad armatures can perform well; however, this performance cannot be maintained beyond the first shot because the titanium armature claddings cause significant damage to the rails. Index Terms--Armature, cladding, railgun, titanium, transition to arcing contact.

Published

2007

36. Modeling assumptions for railguns

Author

Watt, T.J. and Bryant, M.D.

Subjects

Armatures -- Research, Hypervelocity guns -- Research, Thermal stresses -- Research, Business, Electronics, Electronics and electrical industries

Abstract

Insights from recovered armatures suggest re-examining historical modeling assumptions for railguns. The finite-element codes EMAP3D and DYNA3D were linked to explore the effects of temperature-dependent material properties, thermal diffusion, armature wear, inertial loading, thermal stresses, and 2-D model approximations. Temperatures and principal stresses for each of these cases were compared. Thermal diffusion and thermal stresses in armatures cannot be ignored past the first millisecond of launch; material properties under pulsed heating can significantly differ from equilibrium and room-temperature values. Armature wear and inertial loading can be ignored at low speeds, but not at high speeds (>1 km/s). Models in 2-D can approximate 3-D models with appropriate boundary conditions, but only for the first few milliseconds of launch. With a detailed EMAP3D model and minimal assumptions, simulations that agree within a few percentage points of microstructural measurements from recovered armatures are possible. Index Terms--Model assumption, railguns.

Published

2007

37. Modeling thermal stresses in 3-D IC interwafer interconnects

Author

Zhang, Jing, Bloomfield, Max O., Lu, Jian-Qiang, Gutmann, Ronald J., and Cale, Timothy S.

Subjects

Integrated circuits -- Models, Semiconductor chips -- Models, Thermal stresses -- Research, Semiconductor wafers -- Research, Standard IC, Business, Computers, Electronics, Electronics and electrical industries

Abstract

We present a finite-element-based analysis to determine if there are potential reliability concerns due to thermally induced stresses in interwafer copper via structures in three-dimensional (3-D) ICs when benzocyclobutene (BCB) is used as the dielectric adhesive to bond wafers. We first partially validate our approach by comparing computed results against two types of experimental data from planar ICs: 1) volume-averaged thermal stresses measured by X-ray diffraction in an array of parallel Cu lines passivated with TEOS and 2) studies of failures induced by thermal cycling via chain structures embedded in SiLK or SiCOH. In the volume-averaged thermal stress study, predicted stress slopes (d[sigma]/dT) agree well with other modeling results. Our computed stress slopes agree reasonably well with experimental data along the Cu line direction and normal to the Cu lines surface, but we underestimate the stress slope across the Cu line. In the case of via chains, computed von Mises stresses agree with the results of thermal cycle experiments; we predict failure when SiLK is used as a dielectric and predict no failure when SiCOH is used as the dielectric. The approach is then employed to study thermal stresses in interwafer Cu vias in 3-D IC structures bonded with BCB. Simulations show that the von Mises stresses in interwafer Cu vias decrease with decreasing pitch at constant via size, increase with decreasing via size at constant pitch, and decrease with decreasing BCB thickness. We conclude that there is a concern regarding the stability of interwafer Cu vias. Guidelines for design parameter values are estimated, e.g., interwafer via size, pitch, and BCB thickness. For 2.6-/[micro]m-thick BCB, computations indicate that via size should be larger than 3 [micro]m at a pitch of 10 [micro]m to avoid plastic yield of Cu vias. Index Terms--Benzocyclobutene (BCB), Cu, interwafer vias, low-k dielectronics, thermo-mechanical stresses, three-dimensional (3-D) ICs.

Published

2006

38. A study of thermal stress and intrinsic residual stress in planar metallization for integrated power modules

Author

Zhu, Ning, van Wyk, Jacobus Daniel, Liang, Zhenxian, and Odendaal, Willem G. Hardus

Subjects

Thermal stresses -- Research, Business, Computers, Electronics, Electronics and electrical industries

Abstract

In integrated power modules, mechanical properties of interfaces between deposited copper traces and substrates are important for reliable operation. This paper investigates the values of thermomechanical stresses by IDEAS simulation and describes an experimental method to calculate intrinsic residual stresses using the Stoney equation based on the bending curvature of the sample. Index Terms--Intrinsic residual stress, planar metallization, thermomechanical stress.

Published

2005

39. Intracellular and extracellular components as bacterial thermometers, and early warning against thermal stress

Author

Rowbury, Robin J.

Subjects

Bacteria -- Research, Sensors -- Research, Thermal stresses -- Research, Thermal stresses -- Control, Science and technology

Abstract

ABSTRACT Responses induced by cold or heat are triggered following detection of temperature changes by specific sensing molecules, complexes or structures. Low temperature responses are often induced following sensing of [...]

Published

2005

40. Changes in the fluorescence of the Caribbean coral Montastraea faveolata during heat-induced bleaching

Author

Zawada, David G. and Jaffe, Jules S.

Subjects

Caribbean Sea -- Natural history, Corals -- Research, Color of animals -- Research, Thermal stresses -- Research, Fluorescence -- Physiological aspects, Earth sciences

Abstract

In order to evaluate the response of commonly occurring green and orange fluorescent host-based pigments, a thermal stress experiment was performed on specimens of the Caribbean coral Montastraea faveolata. Seven paired samples were collected from a small oceanic reef near Lee Stocking Island in the Bahamas. Seven of the fourteen corals were subjected to elevated temperatures for 28 d, followed by a recovery period lasting 53 d. Throughout the experiment, high-resolution (~400 [micro]m [pixel.sup.-1]) multispectral images of induced fluorescence were recorded at wavelengths corresponding to the green and orange host pigments, plus chlorophyll. These images revealed that the fluorescence of both host pigments was concentrated at polyp centers and declined by 70-90% in regions between polyps. Chlorophyll fluorescence, however, was distributed almost uniformly across the entire coral surface, but with decreases of 10-30% around polyp centers. A normalized difference ratio between the green and orange pigments (GO ratio) was developed to facilitate comparison with chlorophyll fluorescence as a bleaching indicator. Analysis showed a high correspondence between a sustained GO ratio of less than zero and the death of corals. Finally, this ratio was resistant to contamination from other sources of chlorophyll fluorescence, such as filamentous algae.

Published

2003

41. Interlaminar stress analysis of shell structures with piezoelectric patch including thermal loading

Author

Kim, Heung Soo, Zhou, Xu, and Chattopadhyay, Aditi

Subjects

Piezoelectric materials -- Research, Thermal stresses -- Research, Shell roofs -- Models, Shell roofs -- Research, Laminar flow -- Research, Structural engineering -- Research, Aerospace and defense industries, Business

Abstract

Interlaminar stress distribution in smart composite shells using a coupled thermal-piezoelectric-mechanical model is investigated. To maintain local accuracy of stress distributions, the trial displacement field is assumed layerwise higher order and Co continuous through the entire laminate thickness, accommodating zigzag in-plane warping and interlaminar shear stress continuity. The temperature and electrical fields are modeled using higher. order descriptions that can satisfy surface flux boundary conditions at structural surfaces and equipotential conditions at electrode surfaces. These assumptions ensure computational efficiency. A variational principle, addressing the interaction between thermal, piezoelectric, and mechanical fields, is used to derive the governing equations of equilibrium. The proposed theory is used to investigate the cylindrical bending problem of simply supported composite host structures with attached piezoelectric actuators, subject to a combination of mechanical, piezoelectric, and thermal loading. The interlaminar stress distributions under comprehensive loading are presented for different geometries and stacking sequences. The effects of two-way piezoelectric and thermal coupling on the stress distributions are investigated. The significance of the thermal mismatch effect on interlaminar stress distribution is also discussed. The results from present theory are validated with available exact elasticity solutions.

Published

2002

42. Exact solution for thermoelastic deformations of functionally graded thick rectangular plates

Author

Vel, Senthil S. and Batra, R.C.

Subjects

Plates (Engineering) -- Analysis, Deformations (Mechanics) -- Research, Thermal stresses -- Research, Aerospace and defense industries, Business

Abstract

An exact solution is obtained for three-dimensional deformations of a simply supported functionally graded rectangular plate subjected to mechanical and thermal loads on its top and/or bottom surfaces. Suitable temperature and displacement functions that identically satisfy boundary conditions at the edges are used to reduce the partial differential equations governing the thermomechanical deformations to a set of coupled ordinary differential equations in the thickness coordinate, which are then solved by employing the power series method. The exact solution is applicable to both thick and thin plates. Results are presented for two-constituent metal--ceramic functionally graded rectangular plates that have a power law through-the-thickness variation of the volume fractions of the constituents. The effective material properties at a point are estimated by either the Mori--Tanaka or the self-consistent schemes. Exact displacements and stresses at several locations for mechanical and thermal loads are used to assess the accuracy of the classical plate theory, the first-order shear deformation theory, and a third-order shear deformation theory for functionally graded plates. Results are also computed for a functionally graded plate with material properties derived by the Mori--Tanaka method, the self-consistent scheme, and a combination of these two methods.

Published

2002

43. First-order-theory-based thermoelastic stability of functionally graded material circular plates

Author

Najafizadeh, M.M. and Eslami, M.R.

Subjects

Plates (Engineering) -- Analysis, Structural stability -- Analysis, Thermal stresses -- Research, Aerospace and defense industries, Business

Abstract

Thermal buckling of circular plates made of functionally graded material is discussed. The nonlinear equilibrium and linear stability equations are derived using variational formulations. The thermal buckling of solid circular plates under uniform temperature rise, gradient through the thickness, and linear temperature variation along the radius are considered, and the buckling temperatures are derived. The buckling temperatures are derived for simply supported and clamped edges. The results are verified with known results in the literature.

Published

2002

44. Thermal stresses in functionally graded beams

Author

Sankar, Bhavani V. and Tzeng, Jerome T.

Subjects

Viscous flow -- Research, Thermal stresses -- Research, Girders -- Research, Aerospace and defense industries, Business

Abstract

Thermoelastic equilibrium equations for a functionally graded beam are solved in closed-form to obtain the axial stress distribution. The thermoelastic constants of the beam and the temperature were assumed to vary exponentially through the thickness. The Poisson ratio was held constant. The exponential variation of the elastic constants and the temperature allow exact solution for the plane thermoelasticity equations. A simple Euler-Bernoulli-type beam theory is also developed based on the assumption that plane sections remain plane and normal to the beam axis. The stresses were calculated for cases for which the elastic constants vary in the same manner as the temperature and vice versa. The residual thermal stresses are greatly reduced, when the variation of thermoelastic constants are opposite to that of the temperature distribution. When both elastic constants and temperature increase through the thickness in the same direction, they cause a significant raise in thermal stresses. For the case of nearly uniform temperature along the length of the beam, beam theory is adequate in predicting thermal residual stresses.

Published

2002

45. Laboratory studies of thermotolerance acquisition during seed imbibition and germination

Author

Choinski, John S., Jr.

Subjects

Biology -- Study and teaching, Thermal stresses -- Research, Seedlings -- Research, Germination -- Research

Published

1999

46. Heterothermal acclimation: an experimental paradigm for studying the control of thermal acclimation in crabs

Author

Cuculescu, Mirela, Pearson, Timothy, Hyde, David, and Bowler, Ken

Subjects

Crabs -- Physiological aspects, Thermal stresses -- Research, Acclimatization -- Research, Science and technology

Abstract

A method for the study of the control of the attainment of thermal acclimation has been applied to the crabs, Cancer pagurus and Carcinus maenas. Crabs were heterothermally acclimated by using an anterior-posterior partition between two compartments, one at 8 [degrees] C and the other at 22 [degrees] C. One compartment held a three-quarter section of the crab including the central nervous system (CNS), eye stalks, and ipsilateral legs; the other held a quarter section including the contralateral legs. Criteria used to assess the acclimation responses were comparisons of muscle plasma membrane fatty acid composition and 'fluidity.' In both species, the major fatty acids of phosphatidylcholine were 16:0, 18:1, 20:5, and 22:6, whereas phosphatidylethanolamine contained significantly less 16:0 but more 18:0; these fatty acids comprised 80% of the total. Differences in fatty acid composition were demonstrated between fractions obtained from the ipsilateral and contralateral legs from the same heterothermally acclimated individual. In all acclimation states (except 22CNS, phosphatidylcholine fraction), membrane lipid saturation was significantly increased with acclimation at 22 [degrees] as compared with 8 [degrees] C. Membrane fluidity was determined by using 1,3-diphenyl-1,3,5 hexatriene (DPH) fluorescence polarization. In both species, membranes from legs held at 8 [degrees] were more fluid than from legs held at 22 [degrees] C irrespective of the acclimation temperature of the CNS. Heterothermal acclimation demonstrated that leg muscle membrane composition and fluidity respond primarily to local temperature and were not predominately under central direction. The responses between 8 [degrees] C- and 22 [degrees] C-acclimated legs were more pronounced when the CNS was cold-acclimated, so a central influence cannot be excluded.

Published

1999

47. Residual capacity of HSC thermally damaged deep beams

Author

Felicetti, Roberto, Gambarova, Pietro G., and Semiglia, Marina

Subjects

High strength concrete -- Research, Girders -- Research, High temperatures -- Research, Thermal stresses -- Research, Engineering and manufacturing industries, Science and technology

Abstract

High-strength concretes containing siliceous aggregates are very sensitive to high temperatures, as shown by the marked decrease of their mechanical properties both at high temperatures and after cooling down to room temperature (residual properties). However, because of the greater nonlinearity of concrete due to thermal damage, the structural behavior is generally less affected by high temperatures than the constitutive behavior, as is shown in this study on the residual behavior of three lightly reinforced and three unreinforced deep beams ([f.sub.c] = 72 MPa). Four specimens were tested after a single thermal cycle (T = 250 or 400[degrees]C) and two specimens were tested in the virgin state (T = 20[degrees]C), in order (1) to measure the complete load-displacement response in three-point bending; (2) to study crack formation; and (3) to assess the roles of the various 'complementary' shear resistant mechanisms. The results show that the ultimate capacity decreases markedly in the unreinforced specimens, but not as much as the tensile strength, and that the role of the complementary shear-resistant mechanisms increases in both reinforced and unreinforced beams, in spite of the worsening mechanical properties of concrete.

Published

1999

48. Thermal and mechanical stress in induction coilguns

Author

Becherini, G., Tellini, A., and Raugi, M.

Subjects

Mechanical wear -- Research, Thermal stresses -- Research, Induction coils -- Research, Business, Electronics, Electronics and electrical industries

Abstract

The aim of this paper is to define a procedure for the design of induction coilguns in order to obtain thermal and mechanical stress that do not exceed the allowed values in the sleeve. The magnetic vector potential is determined considering a cylindrical sheet current model both for the barrel and the sleeve and solving the related modified Bessel equation. Then the flux, the current density and the propulsive force for each section are determined. By considering the constraints due to mechanical and thermal stress, the maximum muzzle velocity for a one-section launcher is determined. Supposing that the muzzle velocities in the first and in the last section are established, and assuming that all sections, from the second to the last, work with the same mean slip and the same relative velocity, the number of sections and their length are determined. Moreover the surface current density in the barrel is calculated. The design criterion is compared with other criteria, and then used to design an 8km/s muzzle velocity launcher. Index terms - induction coilguns stresses.

Published

1999

49. Structural optimization with thermal and mechanical constraints

Author

Xu, Suqiang and Grandhi, Ramana V.

Subjects

Structural optimization -- Research, Thermal stresses -- Research, Aerospace and defense industries, Business, Science and technology

Abstract

The application of new approximation tools for thermal structural approximation has been evaluated. The method has been used to calculate the minimum mass design of structures subjected to stress, displacement and temperature constraints. The efficiency of the method is based on the two-point approximation of the function, consideration of coupling between the heat transfer and structural analysis and approximation of the internal forces instead of stresses.

Published

1999

50. Analysis of composite panels subjected to thermo-mechanical loads

Author

Noor, Ahmed K. and Peters, Jeanne M.

Subjects

Composite materials -- Analysis, Plates (Engineering) -- Analysis, Thermal stresses -- Research, Materials -- Dynamic testing, Aerospace and defense industries, Engineering and manufacturing industries, Science and technology

Abstract

The results of a detailed study of the effect of cutout on the nonlinear response of curved unstiffened panels are presented. The panels are subjected to combined temperature gradient through-the-thickness combined with pressure loading and edge shortening or edge shear. The analysis is based on a first-order, shear-deformation, Sanders-Budiansky-type shell theory with the effects of large displacements, moderate rotations, transverse shear deformation, and laminated anisotropic material behavior included. A mixed formulation is used with the fundamental unknowns consisting of the generalized displacements and the stress resultants of the panel. The nonlinear displacements, strain energy, principal strains, transverse shear stresses, transverse shear strain energy density, and their hierarchical sensitivity coefficients are evaluated. The hierarchical sensitivity coefficients measure the sensitivity of the nonlinear response to variations in the panel parameters, as well as in the material properties of the individual layers. Numerical results are presented for cylindrical panels and show the effects of variations in the loading and the size of the cutout on the global and local response quantities as well as their sensitivity to changes in the various panel, layer, and micromechanical parameters.

Published

1999