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@@ -270,7 +270,7 @@ @article{ ISI:000085724100006 | |
Web-of-Science-Categories = {{Construction \& Building Technology; Materials Science, | ||
Multidisciplinary}}, | ||
Author-Email = {{ [email protected] }}, | ||
Author-Email = {{Jacques Marchand}}, | ||
Author-Name = {{Jacques Marchand}}, | ||
ResearcherID-Numbers = {{Chen, Wei/A-5694-2010}}, | ||
Number-of-Cited-References = {{22}}, | ||
Times-Cited = {{111}}, | ||
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@@ -584,3 +584,58 @@ @gsj.go.jp | |
DA = {{2017-08-29}}, | ||
} | ||
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@article{ ISI:000088336900008, | ||
Author = {Rizzi, E and Papa, E and Corigliano, A}, | ||
Title = {{Mechanical behavior of a syntactic foam: experiments and modeling}}, | ||
Journal = {{INTERNATIONAL JOURNAL OF SOLIDS AND STRUCTURES}}, | ||
Year = {{2000}}, | ||
Volume = {{37}}, | ||
Number = {{40}}, | ||
Pages = {{5773-5794}}, | ||
Month = {{OCT}}, | ||
Abstract = {{This paper reports the results of a research activity concerning the | ||
mechanical behavior of a syntactic foam employed as core material for | ||
sandwich composite panels. Following a purely phenomenological approach, | ||
experimental and numerical results are presented and compared at the | ||
macroscopic scale. The main features observed in the uniaxial, biaxial | ||
and Three Point Bending (TPB) tests are highlighted. A bimodulus | ||
constitutive model of the Drucker-Prager type is chosen for modeling | ||
biaxial stress states with diffused damage. An alternative discrete | ||
crack approach is devised for the computer simulation of the (TPB) three | ||
point bending tests: the best matching is achieved for a rectangular | ||
Dugdale-type cohesive law. Though not proposing novel experimental or | ||
numerical methodologies, the present engineering approach should | ||
interest readers generally involved in computational composite mechanics | ||
and, specifically, in modeling particulate composites of the type | ||
considered here. (C) 2000 Elsevier Science Ltd. All rights reserved.}}, | ||
Publisher = {{PERGAMON-ELSEVIER SCIENCE LTD}}, | ||
Address = {{THE BOULEVARD, LANGFORD LANE, KIDLINGTON, OXFORD OX5 1GB, ENGLAND}}, | ||
Type = {{Article}}, | ||
Language = {{English}}, | ||
Affiliation = {{Corigliano, A (Reprint Author), Politecn Milan, Dipartimento Ingn Strutturale, Piazza Leonardo da Vinci 32, I-20133 Milan, Italy. | ||
Politecn Milan, Dipartimento Ingn Strutturale, I-20133 Milan, Italy. | ||
Politecn Bari, Fac Ingn Taranto, Dipartimento Ingn Strutturale, I-70125 Bari, Italy.}}, | ||
DOI = {{10.1016/S0020-7683(99)00264-4}}, | ||
ISSN = {{0020-7683}}, | ||
Keywords = {{composites; syntactic foams; experiments; uniaxial tension/compression; | ||
biaxial compression; three point bending; constitutive models; cohesive | ||
laws; finite element simulations}}, | ||
Keywords-Plus = {{COMPOSITES; FRACTURE}}, | ||
Research-Areas = {{Mechanics}}, | ||
Web-of-Science-Categories = {{Mechanics}}, | ||
ResearcherID-Numbers = {{RIZZI, Egidio/C-2263-2017}}, | ||
ORCID-Numbers = {{RIZZI, Egidio/0000-0002-6734-1382}}, | ||
Number-of-Cited-References = {{49}}, | ||
Times-Cited = {{85}}, | ||
Usage-Count-Last-180-days = {{4}}, | ||
Usage-Count-Since-2013 = {{38}}, | ||
Journal-ISO = {{Int. J. Solids Struct.}}, | ||
Doc-Delivery-Number = {{337BF}}, | ||
Unique-ID = {{ISI:000088336900008}}, | ||
OA = {{No}}, | ||
DA = {{2017-08-29}}, | ||
Author-Email = {{ [email protected] }}, | ||
Author-Name = {{AlbertoCorigliano}}, | ||
} | ||
>>>>>>> e7606b1ddd0783f854bac725841cddba3f9c8155 | ||
>>>>>>> 6a1954193341f5a9778bd22ef9da66ef42836cc7 |
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@@ -693,3 +693,57 @@ @umist.ac.uk | |
Author-Name={L. Babout}, | ||
Data={N/A} | ||
} | ||
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@article{ ISI:000225845800040, | ||
Author = {Guo, YB and Yen, DW}, | ||
Title = {{A FEM study on mechanisms of discontinuous chip formation in hard | ||
machining}}, | ||
Journal = {{JOURNAL OF MATERIALS PROCESSING TECHNOLOGY}}, | ||
Year = {{2004}}, | ||
Volume = {{155}}, | ||
Number = {{2, SI}}, | ||
Pages = {{1350-1356}}, | ||
Month = {{NOV 30}}, | ||
Abstract = {{Chip types in machining are determined by the combined effects of | ||
workpiece material properties, cutting speed, and tool geometry. The | ||
understanding of chip formation plays an important role in machining | ||
process optimization and surface integrity. Discontinuous chips, one of | ||
the major chip types, are usually formed in hard machining at high | ||
speeds. In this study, a new method has been presented to simulate | ||
discontinuous chips in high-speed machining AISI 4340 (32 HRc). The | ||
workpiece material properties have been modeled using the Johnson-Cook | ||
(JC) plasticity model, and material crack formation and propagation | ||
simulated using the Johnson-Cook damage model. It has been shown that | ||
discontinuous chip is due to the internal crack initiation and | ||
propagation in front of the tool and above the cutting edge, rather than | ||
from the free surface. The simulated chip morphology correlated well | ||
with the experimental results. (C) 2004 Elsevier B.V. All rights | ||
reserved.}}, | ||
Publisher = {{ELSEVIER SCIENCE SA}}, | ||
Address = {{PO BOX 564, 1001 LAUSANNE, SWITZERLAND}}, | ||
Type = {{Article}}, | ||
Language = {{English}}, | ||
Affiliation = {{Guo, YB (Reprint Author), Univ Alabama, Dept Engn Mech, Tuscaloosa, AL 35487 USA. | ||
Univ Alabama, Dept Engn Mech, Tuscaloosa, AL 35487 USA. | ||
Delphi E\&C Dayton Tech Ctr, Dayton, OH 45408 USA.}}, | ||
DOI = {{10.1016/j.jmatprotec.2004.04.210}}, | ||
ISSN = {{0924-0136}}, | ||
Keywords = {{finite element analysis; discontinuous chips; hard machining}}, | ||
Keywords-Plus = {{SHEAR INSTABILITY; SIMULATION}}, | ||
Research-Areas = {{Engineering; Materials Science}}, | ||
Web-of-Science-Categories = {{Engineering, Industrial; Engineering, Manufacturing; Materials Science, | ||
Multidisciplinary}}, | ||
Author-Email = {{[email protected] | ||
[email protected]}}, | ||
Number-of-Cited-References = {{22}}, | ||
Times-Cited = {{75}}, | ||
Usage-Count-Last-180-days = {{2}}, | ||
Usage-Count-Since-2013 = {{25}}, | ||
Journal-ISO = {{J. Mater. Process. Technol.}}, | ||
Doc-Delivery-Number = {{881EI}}, | ||
Unique-ID = {{ISI:000225845800040}}, | ||
OA = {{No}}, | ||
DA = {{2017-08-29}}, | ||
} | ||
|
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@@ -619,3 +619,58 @@ @hiroshima-u.ac.jp | |
Author-Name={Thomas Mitchell}, | ||
Data={N/A} | ||
} | ||
|
||
@article{ ISI:000251857100009, | ||
Author = {Hallett, Stephen R. and Jiang, Wen-Guang and Khan, Bijoysri and Wisnom, | ||
Michael R.}, | ||
Title = {{Modelling the interaction between matrix cracks and delamination damage | ||
in scaled quasi-isotropic specimens}}, | ||
Journal = {{COMPOSITES SCIENCE AND TECHNOLOGY}}, | ||
Year = {{2008}}, | ||
Volume = {{68}}, | ||
Number = {{1}}, | ||
Pages = {{80-89}}, | ||
Month = {{JAN}}, | ||
Abstract = {{A series of tensile tests on scaled quasi-isotropic laminates have been | ||
carried out and modelled using finite element analysis to predict | ||
failure. Observations during testing and examination of the failed test | ||
specimens showed significant influence of matrix cracking and | ||
delamination on the final failure. Initially the virtual crack closure | ||
technique (VCCT) was used to determine the applied load that would cause | ||
free edge delamination. Experimental results showed that failure | ||
occurred at loads lower than those predicted. Matrix cracks, observed in | ||
the testing, were introduced into the model and interface elements were | ||
used to model the delamination development. This approach gave good | ||
correlation to the behaviour observed in the tests. Even in the | ||
specimens apparently dominated by fibre failure, delamination was shown | ||
to be significant. (c) 2007 Elsevier Ltd. All rights reserved.}}, | ||
Publisher = {{ELSEVIER SCI LTD}}, | ||
Address = {{THE BOULEVARD, LANGFORD LANE, KIDLINGTON, OXFORD OX5 1GB, OXON, ENGLAND}}, | ||
Type = {{Article}}, | ||
Language = {{English}}, | ||
Affiliation = {{Hallett, SR (Reprint Author), Univ Bristol, Dept Aeronaut Engn, Bristol BS8 1TR, Avon, England. | ||
Hallett, Stephen R.; Jiang, Wen-Guang; Khan, Bijoysri; Wisnom, Michael R., Univ Bristol, Dept Aeronaut Engn, Bristol BS8 1TR, Avon, England.}}, | ||
DOI = {{10.1016/j.compscitech.2007.05.038}}, | ||
ISSN = {{0266-3538}}, | ||
Keywords = {{strength; delamination; transverse cracking; finite element analysis}}, | ||
Keywords-Plus = {{FINITE-ELEMENT-METHOD; COMPOSITE-MATERIALS; PREDICTION; SIMULATION; | ||
GROWTH}}, | ||
Research-Areas = {{Materials Science}}, | ||
Web-of-Science-Categories = {{Materials Science, Composites}}, | ||
Author-Email = {{[email protected]}}, | ||
Author-Name={{Stephen Hallet}}, | ||
ResearcherID-Numbers = {{Wisnom, Michael/A-4413-2008 | ||
Hallett, Stephen/D-2573-2011}}, | ||
ORCID-Numbers = {{Hallett, Stephen/0000-0003-0751-8323}}, | ||
Number-of-Cited-References = {{22}}, | ||
Times-Cited = {{62}}, | ||
Usage-Count-Last-180-days = {{1}}, | ||
Usage-Count-Since-2013 = {{11}}, | ||
Journal-ISO = {{Compos. Sci. Technol.}}, | ||
Doc-Delivery-Number = {{244HN}}, | ||
Unique-ID = {{ISI:000251857100009}}, | ||
OA = {{No}}, | ||
DA = {{2017-08-29}}, | ||
Data={{N/A}} | ||
} | ||
|
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@@ -707,6 +707,7 @@ @umanitoba.ca | |
Data={N/A} | ||
} | ||
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||
@article{ ISI:000289766200012, | ||
Author = {Ozbolt, Josko and Sharma, Akanshu and Reinhardt, Hans-Wolf}, | ||
Title = {{Dynamic fracture of concrete - compact tension specimen}}, | ||
|
@@ -812,7 +813,9 @@ @article{ ISI:000279477200004 | |
Keywords = {{Deicer; Portland cement concrete; SEM; EDX; Freeze-thaw}}, | ||
Keywords-Plus = {{ALKALI-SILICA REACTION; MORTARS; CORROSION; EXPANSION; WATER}}, | ||
Research-Areas = {{Construction \& Building Technology; Engineering; Materials Science}}, | ||
Web-of-Science-Categories = {{Construction \& Building Technology; Engineering, Civil; Materials | ||
Web-of-Science-Categories = {{Construction \& Buil | ||
ding Technology; Engineering, Civil; Materials | ||
Science, Multidisciplinary}}, | ||
Author-Email = {{xianming\[email protected]}}, | ||
Author-Name={Xianming Shi}, | ||
|
@@ -841,4 +844,5 @@ @coe.montana.edu | |
Unique-ID = {{ISI:000279477200004}}, | ||
OA = {{No}}, | ||
DA = {{2017-08-29}}, | ||
} | ||
} | ||
|
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@@ -675,3 +675,58 @@ @imr.ac.cn | |
DA = {{2017-08-29}}, | ||
} | ||
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@article{ ISI:000322706000023, | ||
Author = {Li Longbiao and Song Yingdong and Sun Youchao}, | ||
Title = {{Estimate Interface Shear Stress of Unidirectional C/SiC Ceramic Matrix | ||
Composites from Hysteresis Loops}}, | ||
Journal = {{APPLIED COMPOSITE MATERIALS}}, | ||
Year = {{2013}}, | ||
Volume = {{20}}, | ||
Number = {{4}}, | ||
Pages = {{693-707}}, | ||
Month = {{AUG}}, | ||
Abstract = {{The tensile-tensile fatigue behavior of unidirectional C/SiC ceramic | ||
matrix composites at room and elevated temperature has been | ||
investigated. An approach to estimate the interface shear stress of | ||
ceramic matrix composites under fatigue loading has been developed. | ||
Based on the damage mechanisms of fiber sliding relative to matrix in | ||
the interface debonded region upon unloading and subsequent reloading, | ||
the unloading interface reverse slip length and reloading interface new | ||
slip length are determined by the fracture mechanics approach. The | ||
hysteresis loss energy for the strain energy lost per volume during | ||
corresponding cycle is formulatd in terms of interface shear stress. By | ||
comparing the experimental hysteresis loss energy with the computational | ||
values, the interface shear stress of unidirectional C/SiC ceramic | ||
composites corresponding to different cycles at room and elevated | ||
temperatures has been predicted.}}, | ||
Publisher = {{SPRINGER}}, | ||
Address = {{VAN GODEWIJCKSTRAAT 30, 3311 GZ DORDRECHT, NETHERLANDS}}, | ||
Type = {{Article}}, | ||
Language = {{English}}, | ||
Affiliation = {{Li, LB (Reprint Author), Nanjing Univ Aeronaut \& Astronaut, Coll Civil Aviat, 29 Yudao St, Nanjing 210016, Peoples R China. | ||
Li Longbiao; Sun Youchao, Nanjing Univ Aeronaut \& Astronaut, Coll Civil Aviat, Nanjing 210016, Peoples R China. | ||
Song Yingdong, Nanjing Univ Aeronaut \& Astronaut, Coll Energy \& Power Engn, Nanjing 210016, Peoples R China.}}, | ||
DOI = {{10.1007/s10443-012-9297-0}}, | ||
ISSN = {{0929-189X}}, | ||
Keywords = {{Ceramic matrix composites; C/SiC; Fatigue; Interface shear stress; | ||
Hysteresis loops; Matrix cracking; Interface debonding}}, | ||
Keywords-Plus = {{MECHANICAL HYSTERESIS; OUT TESTS; FATIGUE; BEHAVIOR; FRICTION; CRACKING}}, | ||
Research-Areas = {{Materials Science}}, | ||
Web-of-Science-Categories = {{Materials Science, Composites}}, | ||
Author-Email = {{[email protected]}}, | ||
Author-Name={{Li Longbiao}}, | ||
Funding-Acknowledgement = {{Postdoctoral Science Foundation of China {[}2012M511274]}}, | ||
Funding-Text = {{This work is sponsored by the Postdoctoral Science Foundation of China | ||
(Grant No. 2012M511274).}}, | ||
Number-of-Cited-References = {{24}}, | ||
Times-Cited = {{26}}, | ||
Usage-Count-Last-180-days = {{2}}, | ||
Usage-Count-Since-2013 = {{20}}, | ||
Journal-ISO = {{Appl. Compos. Mater.}}, | ||
Doc-Delivery-Number = {{195MF}}, | ||
Unique-ID = {{ISI:000322706000023}}, | ||
OA = {{No}}, | ||
DA = {{2017-08-29}}, | ||
} | ||
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