{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"通过对4种碳钢和合金钢的低周疲劳实验,分析了它们的滞回能循环特性及其变化规律,并确定了具有不同循环特性的滞回能数学描述,在实验基础上,提出了疲劳失效的定义,建立了循环滞回能和总失效吸收能与失效寿命之间的实验关系式。讨论了疲劳损伤与滞回能之间关系。","authors":[{"authorName":"童小燕","id":"362b96c1-abdf-4994-a95c-830a7052477f","originalAuthorName":"童小燕"},{"authorName":"王德俊","id":"7ccf1bd7-2e3e-4bc3-bfe5-c5da1d5f17d3","originalAuthorName":"王德俊"},{"authorName":"徐灏","id":"a9e97d5a-2bab-48fd-8392-3424e738ff58","originalAuthorName":"徐灏"}],"categoryName":"|","doi":"","fpage":"49","id":"57eb9cd9-6b6b-4cac-a844-00dfb922e328","issue":"5","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"c5f571ea-1c7c-497c-b82f-4ea46593eaaf","keyword":"循环滞回环","originalKeyword":"循环滞回环"},{"id":"8dcf3bce-f4a1-4671-872c-65883212aee9","keyword":"cyclic hysteresis energy","originalKeyword":"cyclic hysteresis energy"},{"id":"a4c6277c-6e9e-49b5-9ba6-b2427d55fd01","keyword":"fatigue failure life","originalKeyword":"fatigue failure life"},{"id":"f8f89a75-52c9-4767-9e0a-ef7b79b09054","keyword":"<span style=\"color:red\">Masing</span> <span style=\"color:red\">material</span>","originalKeyword":"Masing material"},{"id":"5ab26264-d259-4635-9d91-f250a7ba2fb1","keyword":"Non-<span style=\"color:red\">Masing</span> <span style=\"color:red\">material</span>","originalKeyword":"Non-Masing material"}],"language":"zh","publisherId":"0412-1961_1989_5_10","title":"碳钢和合金钢的循环滞回能实验研究","volume":"25","year":"1989"},{"abstractinfo":"A novel water-soluble core <span style=\"color:red\">material</span> composed of polyethylene glycol, sodium chloride, mica powder and plasticizer was prepared. The compressive strength, bend strength, hygroscopic coefficient and the <span style=\"color:red\">material</span> solubility in water were investigated. The results show that the compressive yield strength of the soluble core can reach 1 MPa and the highest compressive strength can reach 4 MPa, the bend strength is as high as 6.65 MPa, the hygroscopic coefficient is lower than 0.22%/month and the solubility of suitable core <span style=\"color:red\">material</span> is 35.7-55.75 g/(min.m(2)). The wax pattern with undercuts was prepared successfully by using the novel water-soluble core <span style=\"color:red\">material</span>.","authors":[],"categoryName":"|","doi":"","fpage":"270","id":"22d3ffa6-093a-467f-a47c-e9b4c532d909","issue":"3","journal":{"abbrevTitle":"CLKXJSY","coverImgSrc":"journal/img/cover/JMST.jpg","id":"11","issnPpub":"1005-0302 ","publisherId":"CLKXJSY","title":"材料科学技术（英文）"},"keywords":[{"id":"3b887f4d-bf97-45c7-a920-f5d11e0e0d4b","keyword":"Investment cast;Core materials;Mechanical properties;Microstructure","originalKeyword":"Investment cast;Core materials;Mechanical properties;Microstructure"}],"language":"en","publisherId":"1005-0302_2010_3_3","title":"Preparation and Properties of a Novel Water Soluble Core <span style=\"color:red\">Material</span>","volume":"26","year":"2010"},{"abstractinfo":"A novel water-soluble core <span style=\"color:red\">material</span> composed of polyethylene glycol, sodium chloride, mica powder and plasticizer was prepared. The compressive strength, bend strength, hygroscopic coefficient and the <span style=\"color:red\">material</span> solubility in water were investigated. The results show that the compressive yield strength of the soluble core can reach 1 MPa and the highest compressive strength can reach 4 MPa, the bend strength is as high as 6.65 MPa, the hygroscopic coefficient is lower than 0.22%/month and the solubility of suitable core <span style=\"color:red\">material</span> is 35.7-55.75 g/(min&middot;m<sup>2</sup>). The wax pattern with undercuts was prepared successfully by using the novel water-soluble core <span style=\"color:red\">material</span>.","authors":[{"authorName":"Weiguo Jiang","id":"a280f273-74ae-486a-8184-4e3752da9e14","originalAuthorName":"Weiguo Jiang"}],"categoryName":"|","doi":"","fpage":"270","id":"718b49ae-8941-4827-a1fa-be2a9c09a0e7","issue":"3","journal":{"abbrevTitle":"CLKXJSY","coverImgSrc":"journal/img/cover/JMST.jpg","id":"11","issnPpub":"1005-0302 ","publisherId":"CLKXJSY","title":"材料科学技术（英文）"},"keywords":[{"id":"29d15d87-3111-437b-99a5-51e90913a034","keyword":"Investment cast","originalKeyword":"Investment cast"},{"id":"2e737357-4f96-4298-9680-b3c03f26a264","keyword":" Core materials","originalKeyword":" Core materials"},{"id":"8d048b89-b0be-4b3c-b937-9bece6081e33","keyword":" Mechanical property","originalKeyword":" Mechanical property"},{"id":"e0987b75-da26-4a34-a18f-b21195b8182d","keyword":"Microstructure","originalKeyword":"Microstructure"}],"language":"en","publisherId":"1005-0302_2010_3_7","title":"Preparation and Properties of a Novel Water Soluble Core <span style=\"color:red\">Material</span>","volume":"26","year":"2010"},{"abstractinfo":"From the viewpoint of systems energy conservation, the influences of <span style=\"color:red\">material</span> flow on its energy consumption in a steel manufacturing process is an important subject. The quantitative analysis of the relationship between <span style=\"color:red\">material</span> flow and the energy intensity is useful to save energy in steel industry. Based on the concept of standard <span style=\"color:red\">material</span> flow diagram, all possible situations of ferric <span style=\"color:red\">material</span> flow in steel manufacturing process are analyzed. The expressions of the influence of <span style=\"color:red\">material</span> flow deviated from standard <span style=\"color:red\">material</span> flow diagram on energy consumption are put forward.","authors":[{"authorName":"YU Qingbo","id":"587acadf-f073-4855-bdbb-7ed22dac2524","originalAuthorName":"YU Qingbo"},{"authorName":"LU Zhongwu","id":"f14d5055-f1c7-4b60-b752-ed861d9cc4db","originalAuthorName":"LU Zhongwu"},{"authorName":"CAI Jiuju","id":"8d8870cc-45b1-49c0-bf59-07f9d355b29f","originalAuthorName":"CAI Jiuju"}],"categoryName":"|","doi":"","fpage":"46","id":"16779355-1aa8-40e0-b268-848d7eb1893d","issue":"2","journal":{"abbrevTitle":"GTYJXBYWB","coverImgSrc":"journal/img/cover/GTYJXBEN.jpg","id":"1","issnPpub":"1006-706X","publisherId":"GTYJXBYWB","title":"钢铁研究学报(英文版)"},"keywords":[{"id":"03db6fbe-a09d-409a-b4b5-f99222a65972","keyword":"steel manufacturing process;<span style=\"color:red\">material</span> flow;energy consumption;calculating method","originalKeyword":"steel manufacturing process;material flow;energy consumption;calculating method"}],"language":"en","publisherId":"1006-706X_2007_2_7","title":"Calculating Method for Influence of <span style=\"color:red\">Material</span> Flow on Energy Consumption in Steel Manufacturing Process","volume":"14","year":"2007"},{"abstractinfo":"An expert system prototype for fibre-reinforced plastic matrix (FRP) composite <span style=\"color:red\">material</span> design, ESFRP, has been developed. The system consists of seven main functional parts: a general inference engine, a set of knowledge bases, a <span style=\"color:red\">material</span> properties algorithm base, an explanation engine, various data bases, several function models and the user interface. The ESFRP can simulate human experts to make design scheme for fibre-reinforced plastics design, FRP layered plates design and FRP typical engineering components design. It can also predict the <span style=\"color:red\">material</span> properties and make strength analysis according to the micro and macro mechanics of composite materials. A satisfied result can be gained through the reiterative design.","authors":[{"authorName":"Qingfen LI","id":"556681c7-1fa1-4946-9cae-f5b19ba3c3ed","originalAuthorName":"Qingfen LI"},{"authorName":" Zhaoxia CUI","id":"e12e921c-d686-4546-b9e5-5120e602d236","originalAuthorName":" Zhaoxia CUI"},{"authorName":" Weimin WANG","id":"1e3966d2-6cc5-45b1-9c17-b8dc2c2ddcce","originalAuthorName":" Weimin WANG"},{"authorName":" Jianhua GAO","id":"ae848834-518e-4675-bf01-873861b1667e","originalAuthorName":" Jianhua GAO"}],"categoryName":"|","doi":"","fpage":"556","id":"8e6b9f7c-2a97-4971-aa37-437a7bf2ea69","issue":"5","journal":{"abbrevTitle":"CLKXJSY","coverImgSrc":"journal/img/cover/JMST.jpg","id":"11","issnPpub":"1005-0302 ","publisherId":"CLKXJSY","title":"材料科学技术（英文）"},"keywords":[],"language":"en","publisherId":"1005-0302_2001_5_6","title":"An expert system in FRP composite <span style=\"color:red\">material</span> design","volume":"17","year":"2001"},{"abstractinfo":"The selection of a structural <span style=\"color:red\">material</span> requires a compromise between strength and ductility. The <span style=\"color:red\">material</span> properties will then be set by the choice of alloy composition and microstructure during synthesis and processing, although the requirements may change during service life. Materials design strategies that allow for a recoverable tuning of the mechanical properties would thus be desirable, either in response to external control signals or in the form of a spontaneous adaptation, for instance in self-healing. We have designed a <span style=\"color:red\">material</span> that has a hybrid nanostructure consisting of a strong metal backbone that is interpenetrated by an electrolyte as the second component. By polarizing the internal interface via an applied electric potential, we accomplish fast and repeatable tuning of yield strength, flow stress, and ductility. The concept allows the user to select, for instance, a soft and ductile state for processing and a high-strength state for service as a structural <span style=\"color:red\">material</span>.","authors":[],"categoryName":"|","doi":"","fpage":"1179","id":"8ef0ebf5-e5e4-4569-90c9-ca8b22b2e736","issue":"6034","journal":{"abbrevTitle":"S","id":"97137e49-3132-4cd3-b014-b6613cbfe3a0","issnPpub":"0036-8075","publisherId":"S","title":"Science"},"keywords":[{"id":"28f794c3-2403-43fb-8000-ff5664484f58","keyword":"crystal plasticity;surface stress;deformation;metals;strain;adsorption;behavior;gold;au","originalKeyword":"crystal plasticity;surface stress;deformation;metals;strain;adsorption;behavior;gold;au"}],"language":"en","publisherId":"0036-8075_2011_6034_1","title":"A <span style=\"color:red\">Material</span> with Electrically Tunable Strength and Flow Stress","volume":"332","year":"2011"},{"abstractinfo":"The microscopic analyses of polycrystalline <span style=\"color:red\">material</span> at high temperature were carried out. The crystal plasticity model proposed by Asaro and Needleman was applied to a polycrystal model in the finite element simulation and the crystal slip system was randomly provided for each crystal. The grain boundary sliding, which was characteristic at high temperature, was also taken into account. It was shown that the inhomogencous deformation develops over the polycrystal and that the strain concentration appears around the triple point of crystal grain boundary.","authors":[{"authorName":"S.Imatani","id":"f2474b04-64a4-4e83-b5a1-d4cbb51885e9","originalAuthorName":"S.Imatani"},{"authorName":" R.Kawakami","id":"48305488-d901-4e26-989d-be5cc00fb3c8","originalAuthorName":" R.Kawakami"},{"authorName":" Y.Kawano","id":"cc9b93f0-6ad8-4502-9d08-ccc052ebdb72","originalAuthorName":" Y.Kawano"}],"categoryName":"|","doi":"","fpage":"350","id":"2790fc22-face-4b29-bcc6-a4dd791b66ec","issue":"4","journal":{"abbrevTitle":"JSXBYWB","coverImgSrc":"journal/img/cover/amse.jpg","id":"49","issnPpub":"1006-7191","publisherId":"JSXBYWB","title":"金属学报(英文版)"},"keywords":[{"id":"dcb7ee84-3fa5-4b9d-bcca-5ad4cdb09593","keyword":"crystal plasticity","originalKeyword":"crystal plasticity"},{"id":"acb5fa27-ee8a-40e7-96ab-c3dd95c89862","keyword":"null","originalKeyword":"null"},{"id":"5f89b6ee-fe07-49ce-9d48-0a477f561edc","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1006-7191_2004_4_29","title":"MICROSCOPIC ANALYSIS OF POLYCRYSTALLINE <span style=\"color:red\">MATERIAL</span> AT HIGH TEMPERATURE","volume":"17","year":"2004"},{"abstractinfo":"Based on the two-parameter phase field model of polycrystalline, the grain growth in polycrystalline <span style=\"color:red\">material</span> during isothermal holding is simulated by using the adaptive finite element method. The calculated results demonstrates that the cusp grain boundaries are inclined to planar and some small grains coarsen into larger ones through grain boundary migration due to the curvature effect. When the grain boundary misorientations are small enough and meet certain energy and geometric conditions, two grains can rotate to reduce external energy of grain boundaries and coarsen into a single grain. All the modelling results are in good agreement with some experimental observations, and the phase-field model can be successfully employed to simulate polycrystalline grain growth.","authors":[],"categoryName":"|","doi":"","fpage":"","id":"22c110a0-421a-4c0d-a5ac-cccef66e8109","issue":"6","journal":{"abbrevTitle":"APS","id":"36b887b6-8083-4722-8735-38a6f6f18130","issnPpub":"1000-3290","publisherId":"APS","title":"Acta Physica Sinica"},"keywords":[{"id":"33df8454-8c01-4720-b7b9-6aca157fbed2","keyword":"phase-field;grain boundary migration;grain rotation;coarsening;austenite-ferrite transformation;low-carbon steel;dendritic growth;spinodal decomposition;mesoscale simulation;boundary migration;binary;alloy;thin-films;rotation;recrystallization","originalKeyword":"phase-field;grain boundary migration;grain rotation;coarsening;austenite-ferrite transformation;low-carbon steel;dendritic growth;spinodal decomposition;mesoscale simulation;boundary migration;binary;alloy;thin-films;rotation;recrystallization"}],"language":"en","publisherId":"1000-3290_2009_6_3","title":"Phase field modelling of grain growth in polycrystalline <span style=\"color:red\">material</span>","volume":"58","year":"2009"},{"abstractinfo":"With the development of modern science and technology, especially computer science, the numerical simulation method has been widely used in <span style=\"color:red\">material</span> hot-working. Mary achievements have been made in this field by using the numerical simulation method. The numerical simulation method,  especially finite element method fully described in this paper.Applications of the numerical simulation method in <span style=\"color:red\">material</span> hot-working are also discussed. Finally, the future of the numerical simulation method is outlined.","authors":[{"authorName":"J. T. Niu","id":"7a620309-c43e-4dab-9e64-5df8240904b1","originalAuthorName":"J. T. Niu"},{"authorName":" H. T. Li","id":"e530bbc5-ec51-4dc5-ba3d-5995f6187887","originalAuthorName":" H. T. Li"},{"authorName":" X. D. Meng and P. Karjaleinen 1) Analysis and Measurement Center","id":"7f5f3350-c3e3-4e78-a8cb-d14ad03aec4a","originalAuthorName":" X. D. Meng and P. Karjaleinen 1) Analysis and Measurement Center"},{"authorName":" Harbin Institute of Technology","id":"0e829360-a96e-4947-9ebd-074ce41652d8","originalAuthorName":" Harbin Institute of Technology"},{"authorName":" Harbin 150001","id":"26c54e9e-ca27-40ee-b91d-89495dc5eb6c","originalAuthorName":" Harbin 150001"},{"authorName":" China 2) Department of Mechanocal Engineering","id":"a43dd834-87e9-4ae9-a4c2-d5867de3663e","originalAuthorName":" China 2) Department of Mechanocal Engineering"},{"authorName":" The University of Oulu","id":"6131bdc1-3ad1-42f9-a95a-4f1433a504b0","originalAuthorName":" The University of Oulu"},{"authorName":" Finland","id":"6f43135d-eec3-4775-808c-45499cd16f87","originalAuthorName":" Finland"}],"categoryName":"|","doi":"","fpage":"494","id":"6c7052f3-2cad-4f15-9a3d-d99a1a01a6c7","issue":"2","journal":{"abbrevTitle":"JSXBYWB","coverImgSrc":"journal/img/cover/amse.jpg","id":"49","issnPpub":"1006-7191","publisherId":"JSXBYWB","title":"金属学报(英文版)"},"keywords":[{"id":"98cf903f-b52f-4d3b-a385-5d0fcd5e2d67","keyword":"numerical simulation","originalKeyword":"numerical simulation"},{"id":"2455b5d8-c078-44fb-b20e-88ab29aa546b","keyword":"null","originalKeyword":"null"},{"id":"e4cf638d-aa84-43cb-98b7-d3560c310989","keyword":"null","originalKeyword":"null"}],"language":"en","publisherId":"1006-7191_2000_2_31","title":"NUMERICAL SIMULATION METHODS AND THEIR APPLICATION IN <span style=\"color:red\">MATERIAL</span> HOT-WORKING","volume":"13","year":"2000"},{"abstractinfo":"Based on the biomimetic route the metal <span style=\"color:red\">material</span> with tree-like fractal structure was prepared, which showed a rough surface observed by scanning electron microscopy. According to the electrochemical experiments, the formed <span style=\"color:red\">material</span> exhibited the strong catalytic capability as an electrode in hydrogen evolution reaction, comparing with other conventional structure materials under comparable scales. We suggested this promotion of property arose from the contribution of the great surface area and the excellent connectivity offered from the fractal structure. (c) 2005 Elsevier B.V. All rights reserved.","authors":[],"categoryName":"|","doi":"","fpage":"486","id":"139a741f-c2c2-4eb3-bbb8-6549e73cd59b","issue":"4","journal":{"abbrevTitle":"MS&ECMSAS","id":"06f61aef-0d03-4337-9821-97176d48139a","issnPpub":"0928-4931","publisherId":"MS&ECMSAS","title":"Materials Science & Engineering C-Biomimetic Materials Sensors and Systems"},"keywords":[{"id":"6920aaaf-90ee-4368-b45d-de6cc723d658","keyword":"biomimetic;fractal;hydrogen evolution reaction;specific surface area;hydrogen evolution reaction;fractal patterns;growth;electrodes;deposition;morphology;devices","originalKeyword":"biomimetic;fractal;hydrogen evolution reaction;specific surface area;hydrogen evolution reaction;fractal patterns;growth;electrodes;deposition;morphology;devices"}],"language":"en","publisherId":"0928-4931_2005_4_1","title":"A branched <span style=\"color:red\">material</span> based on biomimetic design: Synthesis and electrochemical properties","volume":"25","year":"2005"}],"totalpage":128,"totalrecord":1277}