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Online since: August 2012
Authors: Xiang Dong, Shi Ping Zhang
Steel fibers can also reduce cracking, and improve the cracking resistance of concrete materials.
Concrete admixture used was JM–PCA produced by Jiangsu Bote New Materials Co., Ltd.
BK 2011690) and State Key Laboratory of High Performance Civil Engineering Materials ( No. 2010CEM019).
Sun, Studies of the properties of fiber matrix in steel fiber reinforced mortar, ACI Materials Journal 84 (2) (1987) 101-109
Homrich, Tensile stress– strain properties of SIFCON, ACI Materials Journals 86 (3) (1989) 369-377
Concrete admixture used was JM–PCA produced by Jiangsu Bote New Materials Co., Ltd.
BK 2011690) and State Key Laboratory of High Performance Civil Engineering Materials ( No. 2010CEM019).
Sun, Studies of the properties of fiber matrix in steel fiber reinforced mortar, ACI Materials Journal 84 (2) (1987) 101-109
Homrich, Tensile stress– strain properties of SIFCON, ACI Materials Journals 86 (3) (1989) 369-377
Online since: June 2011
Authors: A. Abdullah Kassim, H. Shah Qasim
Introduction
Bi-materials possess a significant importance due to their extensive applications in manufacturing industry where ductile materials maybe joined to comparatively brittle materials or where physically mismatching materials have to be joined to obtain technical or economical objectives.
The bond strength at the bi-materials interface plays a greater role in assuring the joint reliability.
The model of a bi-material notch is suitable to simulate a number of construction points from which a failure is initiated at the junction of two materials at the free surface.
Fujimoto, Numerical Simulation of Impact Transonic Interfacial Fracture with the Crack Coalescence, Materials Science Forum Vols. 465-466 (2004) pp 61-66, (2004) Trans Tech Publications, Switzerland. 4.
Hadavinia, A cohesive zone global energy analysis of an impact loaded bi-material strip in shear, International Journal of Fracture (2006) 138:197–209. 8.
The bond strength at the bi-materials interface plays a greater role in assuring the joint reliability.
The model of a bi-material notch is suitable to simulate a number of construction points from which a failure is initiated at the junction of two materials at the free surface.
Fujimoto, Numerical Simulation of Impact Transonic Interfacial Fracture with the Crack Coalescence, Materials Science Forum Vols. 465-466 (2004) pp 61-66, (2004) Trans Tech Publications, Switzerland. 4.
Hadavinia, A cohesive zone global energy analysis of an impact loaded bi-material strip in shear, International Journal of Fracture (2006) 138:197–209. 8.
Online since: December 2013
Authors: Si Chen, Jin Gang He, Lin Ke, Zheng Li Jiang
Erosion experiment of brittle materials.
Journal of Materials Engineering,1991,1(13):63-70
[3] Aquaro D,Fontani E,Erosion of Ductile and Brittle Materials[J].
[4] Wiederhorn S M,Hockey B J.Effect of material parameters on the erosion resistance of brittle materials[J].
Journal of Materials Science,1983,18(3):766-780
Journal of Materials Engineering,1991,1(13):63-70
[3] Aquaro D,Fontani E,Erosion of Ductile and Brittle Materials[J].
[4] Wiederhorn S M,Hockey B J.Effect of material parameters on the erosion resistance of brittle materials[J].
Journal of Materials Science,1983,18(3):766-780
Online since: September 2011
Authors: Xiu Ling Li, Min Luo
Lepech [17] presented a green materials design framework and completed a case study in the design of green materials for a specific infrastructure application.
Li, Large Scale Processing of Engineered Cementitious Composites, ACI Materials Journal, 105 (2008) 358-366
Li, Use of high volumes of fly ash to improve ECC mechanical properties and material greenness, ACI Materials Journal, 104 (2007) 303-311
Li, Engineered cementitious composites with high-volume fly ash, ACI Materials Journal, 104 (2007) 233-241
Robertson, et al, Design of green engineered cementitious composites for improved sustainability, ACI Materials Journal, 105 (2008) 567-575
Li, Large Scale Processing of Engineered Cementitious Composites, ACI Materials Journal, 105 (2008) 358-366
Li, Use of high volumes of fly ash to improve ECC mechanical properties and material greenness, ACI Materials Journal, 104 (2007) 303-311
Li, Engineered cementitious composites with high-volume fly ash, ACI Materials Journal, 104 (2007) 233-241
Robertson, et al, Design of green engineered cementitious composites for improved sustainability, ACI Materials Journal, 105 (2008) 567-575
Online since: August 2021
Authors: Luiza Silva, Dulcineia Wessel, Isabel Brás, Idalina Domingos, José Ferreira, Elisabete Silva
Some examples of materials used
with this purpose are granite, marble, wood, stainless steel, and new composite engineered
materials.
Materials and Methods Goal of the Study.
LCIA results for various countertop materials.
Journal of Cleaner Production (2015), p. 1 – 14 [3] R.
Journal of Natural and Applied Sciences (2018) [7] DuPont: EPD for Corian Solid Surface.
Materials and Methods Goal of the Study.
LCIA results for various countertop materials.
Journal of Cleaner Production (2015), p. 1 – 14 [3] R.
Journal of Natural and Applied Sciences (2018) [7] DuPont: EPD for Corian Solid Surface.
Online since: May 2017
Authors: Margarita Isaenkova, Evgeny Grigoriev, Artem Lunev, Artem Zazolin, Denis Pchelyakov, Yuri Perlovich, Olga Krymskaya
Plasticity of oxide fuel based on uranium dioxide is one of the less-covered topics in nuclear
materials science.
Ching-Tsven, Dry-ADU process for UO2 production, Journal of Nuclear Materials 199,1 (1992) 61-67
Burkhammer, Sintering of high density uranium dioxide bodies, Journal of Nuclear Materials 2, 2 (1960) 176 - 180
Balzari, Hot-pressing of uranium dioxide, Journal of Nuclear Materials 20, 2 (1966) 210 - 214
Contamin, Uranium and oxygen self-diffusion in UO2, Journal of Nuclear Materials 30, 1 (1969) 16-25
Ching-Tsven, Dry-ADU process for UO2 production, Journal of Nuclear Materials 199,1 (1992) 61-67
Burkhammer, Sintering of high density uranium dioxide bodies, Journal of Nuclear Materials 2, 2 (1960) 176 - 180
Balzari, Hot-pressing of uranium dioxide, Journal of Nuclear Materials 20, 2 (1966) 210 - 214
Contamin, Uranium and oxygen self-diffusion in UO2, Journal of Nuclear Materials 30, 1 (1969) 16-25
Online since: August 2016
Authors: Tomasz Sadowski, Daniel Pietras
., Poland
aemail: t.sadowski@pollub.pl, bemail: pietras140t@gmail.com
Keywords: Thermal barrier coatings, ceramic materials, functionally graded materials
Abstract.
In the classical technology as the TBC protection different types of polycrystalline materials were used (e.g. [1-11]).
[4] V.Birman, L.V.Bryd, Modelling and Analysis of Functionally Graded Materials and Structures.
[9] L.A.Gömze, L.N.Gömze, Alumina-based hetero-modulus ceramic composites with extreme dynamic strength – phase transformation of Si3N4 during high speed collision with metallic bodies, Ĕpitöanyag – Journal of Silicate Based and Composite Materials 61 (2009) 38-42
Watanabe, Thermal fracture behavior of metal/ceramic functionally graded materials, Engineering Fracture Mechanics 69 (2002) 1713–1728 [17] T.Sadowski, D.Pietras, I.Ivanov, Estimation of thermal stress intensity factor in a strip with various property gradations subjected to thermal shock, Key Engineering Materials Vol. 601 (2014) 71-75 [18] Z-H.
In the classical technology as the TBC protection different types of polycrystalline materials were used (e.g. [1-11]).
[4] V.Birman, L.V.Bryd, Modelling and Analysis of Functionally Graded Materials and Structures.
[9] L.A.Gömze, L.N.Gömze, Alumina-based hetero-modulus ceramic composites with extreme dynamic strength – phase transformation of Si3N4 during high speed collision with metallic bodies, Ĕpitöanyag – Journal of Silicate Based and Composite Materials 61 (2009) 38-42
Watanabe, Thermal fracture behavior of metal/ceramic functionally graded materials, Engineering Fracture Mechanics 69 (2002) 1713–1728 [17] T.Sadowski, D.Pietras, I.Ivanov, Estimation of thermal stress intensity factor in a strip with various property gradations subjected to thermal shock, Key Engineering Materials Vol. 601 (2014) 71-75 [18] Z-H.
Online since: March 2023
Authors: S.A. Kuzmin, D.A. Krasilnikov, A.A. Argunova, A.D. Egorova, M.V. Katsurba
Existing materials behave differently in different climatic zones.
Test Materials and Experiment Methodology Amokor is a series of liquid polymeric materials that allows you to return the original physical and mechanical properties and even improve them in structural materials, such as concrete, metal, brick, wood, etc.
The research of durability of constructional materials modified by polymeric Silor-ultra additive, SECTION 3, CONSTRUCTION MATERIALS AND PRODUCTS, p. 228
Emelianova, Research of Durability and Structure of the Heavy Concrete Modified by Polymeric Impregnation in the Frigid Climate, Materials Science Forum.
Kychkin, Wood concrete on the basis of Portland cement with silor-ultra additive, Norwegian Journal of development of the International Science, Oslo, Norway. 27 (2019) 63-66
Test Materials and Experiment Methodology Amokor is a series of liquid polymeric materials that allows you to return the original physical and mechanical properties and even improve them in structural materials, such as concrete, metal, brick, wood, etc.
The research of durability of constructional materials modified by polymeric Silor-ultra additive, SECTION 3, CONSTRUCTION MATERIALS AND PRODUCTS, p. 228
Emelianova, Research of Durability and Structure of the Heavy Concrete Modified by Polymeric Impregnation in the Frigid Climate, Materials Science Forum.
Kychkin, Wood concrete on the basis of Portland cement with silor-ultra additive, Norwegian Journal of development of the International Science, Oslo, Norway. 27 (2019) 63-66
Online since: October 2006
Authors: Maksim Kireitseu
Chung: Journal of Materials Science Vol. 36 (2001), p. 5733
[2] C.E.
(Elsevier Applied Science, London, 2001)
Jin, Journal of Material Science Letters Vol. 12 (1993), p. 252 [34] D.M.
Wilson: ASM Engineered Materials Handbook, (ASm Int.
Shipton, Materials Sc. and Eng.
(Elsevier Applied Science, London, 2001)
Jin, Journal of Material Science Letters Vol. 12 (1993), p. 252 [34] D.M.
Wilson: ASM Engineered Materials Handbook, (ASm Int.
Shipton, Materials Sc. and Eng.
Online since: September 2013
Authors: Xin Rui Gao
The Design, Rapid Manufacture, and Materials of Artificial Porous Bone Structure
Xinrui Gao
Information Science Technology Institute of Hainan University, Haikou, 570228, China
xr_gao2002@aliyun.com
Keywords: Artificial porous bone structure; Rapid manufacture; Materials.
The process and technologies of Additive fabrication (AF) function through materials addition.
Compared to established methods like FDM, the LDM process is the non-heating liquefying processing of materials and could preserve bio-activities of materials.
Materials used nowadays can be divided into several basic groups: synthetic polymers, natural polymers, ceramics, metals, and composites which were blended and have the properties of two or more materials of different classes.
Phytomolecules may chemically relate with scaffold materials for medical applications.
The process and technologies of Additive fabrication (AF) function through materials addition.
Compared to established methods like FDM, the LDM process is the non-heating liquefying processing of materials and could preserve bio-activities of materials.
Materials used nowadays can be divided into several basic groups: synthetic polymers, natural polymers, ceramics, metals, and composites which were blended and have the properties of two or more materials of different classes.
Phytomolecules may chemically relate with scaffold materials for medical applications.