Sort by:
Publication Type:
Open access:
Publication Date:
Periodicals:
Search results
Online since: January 2023
Authors: Yusriah Lazim, Nadia Razali, Nurriswin Jumadi, Nadlene Razali
Journal of Materials. (2014) 1-6
Balaz, Eggshell membrane biomaterial as a platform for applications in materials science, Acta Biomaterialia. 10 (2014) 3827-3843
Journal of King Saud University - Engineering Sciences. (2015) 49-56
International Journal of Science & Technology. (2015) 8-13
Kevern, Development of mix proportion for functional and durable pervious concrete, Materials Science. (2006) 1-12
Balaz, Eggshell membrane biomaterial as a platform for applications in materials science, Acta Biomaterialia. 10 (2014) 3827-3843
Journal of King Saud University - Engineering Sciences. (2015) 49-56
International Journal of Science & Technology. (2015) 8-13
Kevern, Development of mix proportion for functional and durable pervious concrete, Materials Science. (2006) 1-12
Online since: November 2021
Authors: Vjaceslavs Lapkovskis, Vadim Myadelets, Andrey V. Kasperovich
One of the promising ways is the use of rubber waste as a part of various construction materials[1],[4],[5].
They usually produce low-quality materials due to the deterioration of chemical compatibility and/or interfacial interaction between rubber crumb particles and the elastomer matrix.
Nielsen, ‘Models for the Permeability of Filled Polymer Systems’, Journal of Macromolecular Science: Part A - Chemistry, vol. 1, no. 5, pp. 929–942, Aug. 1967, doi: 10.1080/10601326708053745
Hanhi, ‘Feasible incorporation of devulcanised rubber waste in virgin natural rubber’, Journal of Materials Science, vol. 24, no. 41, pp. 8301–8307, 2006, doi: 10.1007/s10853-006-1010-y
Tapale, ‘Comparative analysis of ultrasonically devulcanised unfilled SBR, NR, and EPDM rubbers’, Journal of Applied Polymer Science, vol. 88, no. 2, pp. 434–441, 2003, doi: 10.1002/app.11741
They usually produce low-quality materials due to the deterioration of chemical compatibility and/or interfacial interaction between rubber crumb particles and the elastomer matrix.
Nielsen, ‘Models for the Permeability of Filled Polymer Systems’, Journal of Macromolecular Science: Part A - Chemistry, vol. 1, no. 5, pp. 929–942, Aug. 1967, doi: 10.1080/10601326708053745
Hanhi, ‘Feasible incorporation of devulcanised rubber waste in virgin natural rubber’, Journal of Materials Science, vol. 24, no. 41, pp. 8301–8307, 2006, doi: 10.1007/s10853-006-1010-y
Tapale, ‘Comparative analysis of ultrasonically devulcanised unfilled SBR, NR, and EPDM rubbers’, Journal of Applied Polymer Science, vol. 88, no. 2, pp. 434–441, 2003, doi: 10.1002/app.11741
Online since: February 2012
Authors: Ulf Engel, Ulrich Vierzigmann, Johannes Koch, Marion Merklein
Journal of Manufacturing Science and Engineering, 133(2012)6, in print.
]
Because of the varying conditions concerning surface pressure, it gets obvious that tribological conditions in SBMF are of major importance for the process realization, its stability and for the quality of the produced part.
Additionally, the velocity vectors in Fig. 2 illustrate the improved material flow.
The higher the friction between the specimen and the dies gets, the more the material flow in radial direction is restrained, resulting in an increasing material flow towards the pin cavity and thus to a larger pin height.
Thus, the intended influence on the material flow can be realized.
Due to higher complexity, the tribology of the die is more significant for the material flow than that of the punch.
Additionally, the velocity vectors in Fig. 2 illustrate the improved material flow.
The higher the friction between the specimen and the dies gets, the more the material flow in radial direction is restrained, resulting in an increasing material flow towards the pin cavity and thus to a larger pin height.
Thus, the intended influence on the material flow can be realized.
Due to higher complexity, the tribology of the die is more significant for the material flow than that of the punch.
Online since: September 2011
Authors: Lu Quan Ren, Zhi Wu Han, Yu Qiu Song, Shi Chao Niu, Li Yan Wu
The specimen material was photoreswast SU8 of polymer monosomic, the refractive index is 1.5.
Large: The Journal of Experimental Biology, Vol. 201 (1998), pp. 1307-1313
Ren: Science in China Series E: Technological Sciences, Vol. 50 (2007) No.4, pp. 430-436
Torres: The Journal of Experimental Biology, Vol. 209 (2006), pp. 748-765
Yokogawa: Journal of Photochemistry and Photobiology A: Chemistry, Vol. 145 (2001), pp. 101-106
Large: The Journal of Experimental Biology, Vol. 201 (1998), pp. 1307-1313
Ren: Science in China Series E: Technological Sciences, Vol. 50 (2007) No.4, pp. 430-436
Torres: The Journal of Experimental Biology, Vol. 209 (2006), pp. 748-765
Yokogawa: Journal of Photochemistry and Photobiology A: Chemistry, Vol. 145 (2001), pp. 101-106
Online since: July 2007
Authors: Ke Yang, Bing Chun Zhang, Hua Juan Yang, Yi Bin Ren
Bucci: Journal of Materials Science: Materials in Medicine Vol.10(1999), p.
389-394;
[4] E.
Salnikow: Critical Reviews in Oncology/Hematology Vol.42 (2002), p.35-56; [5] A Yamamoto, Y Kohyama, D Kuroda, T Hanawa: Materials Science and Enginerring: C Vol.24 (2004), p. 737-743
[7] Ren Yibin,Yang Ke,Zhang Bingchun, et al: Journal of Materials Science and Technology Vol.20(2004),p.571-573; [8] ASTM F2229-02, Standard Specification for Wrought, Nitrogen Strengthened 23 Manganese-21 Chromium-1Molybdenum Low-nickel Stainless Steel Alloy Bar and Wire for Surgical Implants (UNS S29108)
[9] Yibin Ren, Ke Yang, Bingchun Zhang: Materials Letters Vol.59 (2005), p. 1785-1789
[10] S Agathopoulos, P Nikolopoulos: Journal of Biomedical Materials Research Vol.29 (1995), p. 421-429
Salnikow: Critical Reviews in Oncology/Hematology Vol.42 (2002), p.35-56; [5] A Yamamoto, Y Kohyama, D Kuroda, T Hanawa: Materials Science and Enginerring: C Vol.24 (2004), p. 737-743
[7] Ren Yibin,Yang Ke,Zhang Bingchun, et al: Journal of Materials Science and Technology Vol.20(2004),p.571-573; [8] ASTM F2229-02, Standard Specification for Wrought, Nitrogen Strengthened 23 Manganese-21 Chromium-1Molybdenum Low-nickel Stainless Steel Alloy Bar and Wire for Surgical Implants (UNS S29108)
[9] Yibin Ren, Ke Yang, Bingchun Zhang: Materials Letters Vol.59 (2005), p. 1785-1789
[10] S Agathopoulos, P Nikolopoulos: Journal of Biomedical Materials Research Vol.29 (1995), p. 421-429
Online since: December 2011
Authors: Hu Cai, Peng Zhang, Yuan Xun Wang
Surface coefficient of heat transfer of materials
temperature (°C)
20
100
200
300
400
500
600
700
800
900
1000
copper electrode (W/m2·°C)
0
11.16
15.31
19.96
25.62
32.57
41.02
51.20
63.29
77.50
94
DP600
(W/m2·°C)
25
Thermoelectric Properties of Materials.
Chicago, USA, 2004, 539~545 [3] Shi G, Westgate S.A, Resistance spot welding of high strength steels, International Journal for the Joining of Materials, 2004, 16 (1)9~14 [4] Agashe S, Zhang H, Selection of schedules based on heat balance in resistance spot welding, Welding Journal, 2003 (7)179~183 [5] Aslanlar S, The effect of nucleus size on mechanical properties in electrical resistance spot welding of sheets used in automotive industry.
Materials and Design, 2006, 27, 125~131 [6] Xu J.H, Jiang X.P, Zeng Q,et al, Optimization of resistance spot welding on the assembly of refractory alloy 50Mo-50Re thin sheet, Journal of Nuclear Materials, 2007, 366, 417~425 [7] Aslanlar S, Ogur A, Ozsarac U, et al, Effect of welding current on mechanical properties of galvanized chromided steel sheets in electrical resistance spot welding, Materials and Design, 2007, 28, 2~7 [8] Kahraman N, The influence of welding parameters on the joint strength of resistance spot-welded titanium sheets, Materials and Design, 2007, 28, 420~427 [9] Bouyousfi B, Sahraoui T, Guessasma S, et al, Effect of process parameters on the physical characteristics of spot weld joints.
Materials and Design, 2007, 28, 414~419 [10] Long X, Khanna S.K, Fatigue properties and failure characterization of spot welded high strength steel sheet, International Journal of Fatigue, 2007 29, 879~886 [11] Sun D.Q, Lang B, Sun D.X, et al, Microstructures and mechanical properties of resistance spot welded magnesium alloy joints, Materials Science and Engineering A, 2007, 460-461: 494 ~498 [12] Kearns W.H, Welding Processes, AWS Welding Handbook, 3. 7th ed.
Journal of Materials Processing Technology, 2008, 327~335 [14] Marashi P, Pouranvari M., Amirabdollahian S, et al, Microstructure and failure behavior of dissimilar resistance spot welds between low carbon galvanized and austenitic stainless steels, Materials Science and Engineering A, 2008, 480 (1-2)175~180 [15] Wang L, Wang M., Lu F.G, Dynamic simulation of resistance spot welding of zinc-coated steels, China Welding, 2006, 15(4)39~42 [16] Gould, Modeling primary dendrite arm spacings in resistance spot welds: PartⅠ-modeling studies, Welding Journal, 1994, 73(4)67~74 [17] Gould, Modeling primary dendrite arm spacings in resistance spot welds: PartⅡ-experimental studies, Welding Journal, 1994, 73(5)91~100
Chicago, USA, 2004, 539~545 [3] Shi G, Westgate S.A, Resistance spot welding of high strength steels, International Journal for the Joining of Materials, 2004, 16 (1)9~14 [4] Agashe S, Zhang H, Selection of schedules based on heat balance in resistance spot welding, Welding Journal, 2003 (7)179~183 [5] Aslanlar S, The effect of nucleus size on mechanical properties in electrical resistance spot welding of sheets used in automotive industry.
Materials and Design, 2006, 27, 125~131 [6] Xu J.H, Jiang X.P, Zeng Q,et al, Optimization of resistance spot welding on the assembly of refractory alloy 50Mo-50Re thin sheet, Journal of Nuclear Materials, 2007, 366, 417~425 [7] Aslanlar S, Ogur A, Ozsarac U, et al, Effect of welding current on mechanical properties of galvanized chromided steel sheets in electrical resistance spot welding, Materials and Design, 2007, 28, 2~7 [8] Kahraman N, The influence of welding parameters on the joint strength of resistance spot-welded titanium sheets, Materials and Design, 2007, 28, 420~427 [9] Bouyousfi B, Sahraoui T, Guessasma S, et al, Effect of process parameters on the physical characteristics of spot weld joints.
Materials and Design, 2007, 28, 414~419 [10] Long X, Khanna S.K, Fatigue properties and failure characterization of spot welded high strength steel sheet, International Journal of Fatigue, 2007 29, 879~886 [11] Sun D.Q, Lang B, Sun D.X, et al, Microstructures and mechanical properties of resistance spot welded magnesium alloy joints, Materials Science and Engineering A, 2007, 460-461: 494 ~498 [12] Kearns W.H, Welding Processes, AWS Welding Handbook, 3. 7th ed.
Journal of Materials Processing Technology, 2008, 327~335 [14] Marashi P, Pouranvari M., Amirabdollahian S, et al, Microstructure and failure behavior of dissimilar resistance spot welds between low carbon galvanized and austenitic stainless steels, Materials Science and Engineering A, 2008, 480 (1-2)175~180 [15] Wang L, Wang M., Lu F.G, Dynamic simulation of resistance spot welding of zinc-coated steels, China Welding, 2006, 15(4)39~42 [16] Gould, Modeling primary dendrite arm spacings in resistance spot welds: PartⅠ-modeling studies, Welding Journal, 1994, 73(4)67~74 [17] Gould, Modeling primary dendrite arm spacings in resistance spot welds: PartⅡ-experimental studies, Welding Journal, 1994, 73(5)91~100
Online since: May 2013
Authors: Uthumporn Kankeaw, Thitiphan Chimsook, Narumon Sianglek
Materials and methods
Plant material
M. pudica leaves was collected from the Chaiyaphum College of Agriculture and Technology, Chaiyaphum, Thailand.
Tsushina: Canadian Journal of Microbiology.
Sereme: Asian Journal of Plant Sciences.
Rojas-Estudillo: Plant Pathology Journal.
Lozoya: Journal of Ethnopharmacology Vol. 53 (1996), p. 143–147 [12] Y.
Tsushina: Canadian Journal of Microbiology.
Sereme: Asian Journal of Plant Sciences.
Rojas-Estudillo: Plant Pathology Journal.
Lozoya: Journal of Ethnopharmacology Vol. 53 (1996), p. 143–147 [12] Y.
Online since: June 2014
Authors: Rajshree B. Jotania, Hemal Khatri, G. Packiaraj
References
[1] P.Tailhades et al. / Journal of Magnetism and Magnetic Materials 193 (1999) 148-151
Goldman, Handbook of Modern Ferromagnetic Materials, Kulwer Academic Publishers, Boston, USA, 1999
Gul et al. / Journal of Magnetism and Magnetic Materials 320 (2008) 270–275
[14] Maaz et al. / Journal of Magnetism and Magnetic Materials 308 (2007) 289–295
/Journal of Magnetism and Magnetic Materials 324 (2012) 2926–2931
Goldman, Handbook of Modern Ferromagnetic Materials, Kulwer Academic Publishers, Boston, USA, 1999
Gul et al. / Journal of Magnetism and Magnetic Materials 320 (2008) 270–275
[14] Maaz et al. / Journal of Magnetism and Magnetic Materials 308 (2007) 289–295
/Journal of Magnetism and Magnetic Materials 324 (2012) 2926–2931
Online since: July 2012
Authors: Qun Li An
Study of Methylene Blue Adsorption on Mesoporus Molecular Sieve from Aqueous Solution
Qunli An1, a
1College of Materials Science and Engineering, Xi’an University of Science and Technology,
Xi’an 710054, P.
Materials and Methods Chemicals.
[2] Beck JS and Vartuli JC: Solid State & Materials Science Vol. 1 (1996), p. 76
[10] Gürses A, Doğar Ç, Yalçın M, Açıkyıldız M, Bayrak R and Karaca S: Journal of Hazardous Materials Vol. 131 (2006B), p. 217
[11] Sohrabnezhad Sh, Pourahmad A and Radaee E: Journal of Hazardous Materials Vol. 170 (2009), p. 184.
Materials and Methods Chemicals.
[2] Beck JS and Vartuli JC: Solid State & Materials Science Vol. 1 (1996), p. 76
[10] Gürses A, Doğar Ç, Yalçın M, Açıkyıldız M, Bayrak R and Karaca S: Journal of Hazardous Materials Vol. 131 (2006B), p. 217
[11] Sohrabnezhad Sh, Pourahmad A and Radaee E: Journal of Hazardous Materials Vol. 170 (2009), p. 184.
Online since: September 2013
Authors: Liang Jun Zhu, Ming Ying Yang, Si Jia Min, Ya Jun Shuai, Guan Shan Zhou, Namita Mandal
Therefore, the efforts are increasingly focused on the composite materials by blending HAp with polymer materials.
George, et al: Nature materials Vol. 9 (2010), p.1004 [5] D.
Visan, et al: Materials Science and Engineering: B Vol. 169 (2010), p.151 [7] X.
Shuai, et al: Journal of Polymer Science Part B: Polymer Physics Vol. 51 (2013), p.742 [9] J.
Hu, et al: Journal of biomedical materials research Part A Vol. 99 (2011), p.327 [10] S.
George, et al: Nature materials Vol. 9 (2010), p.1004 [5] D.
Visan, et al: Materials Science and Engineering: B Vol. 169 (2010), p.151 [7] X.
Shuai, et al: Journal of Polymer Science Part B: Polymer Physics Vol. 51 (2013), p.742 [9] J.
Hu, et al: Journal of biomedical materials research Part A Vol. 99 (2011), p.327 [10] S.