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Online since: February 2018
Authors: Yi Lin Liao, Shu Jun Qiu, Cui Li Xiang, Huan Zhi Zhang, Fen Xu, Yong Jin Zou, Hai Liang Chu, Wei Zhao, Li Xian Sun
Therefore, it is greatly urgent to develop high-performance advanced electrode materials to be used in alkaline secondary batteries.
Cobalt or cobalt-based alloys were developed and used as anode materials in alkaline secondary batteries.
The researchers have been trying to find Co-B alloys with better cycle stability, higher electrochemical capacity, and higher rate discharge-ability used as negative electrode materials for alkaline secondary batteries based on the optimization of preparation methods [11,12], the select of raw materials [3], the control of the synthesizing conditions [13] and multi-component alloying [8,14,15,16].
Wang: An Investigation on the Energy Storage Properties of Co-S Materials in Alkaline Solution (Ph.D., Nankai University, China 2012) p.43
Sun: Key Engineering Materials, Vol. 727 (2017) p.751
Cobalt or cobalt-based alloys were developed and used as anode materials in alkaline secondary batteries.
The researchers have been trying to find Co-B alloys with better cycle stability, higher electrochemical capacity, and higher rate discharge-ability used as negative electrode materials for alkaline secondary batteries based on the optimization of preparation methods [11,12], the select of raw materials [3], the control of the synthesizing conditions [13] and multi-component alloying [8,14,15,16].
Wang: An Investigation on the Energy Storage Properties of Co-S Materials in Alkaline Solution (Ph.D., Nankai University, China 2012) p.43
Sun: Key Engineering Materials, Vol. 727 (2017) p.751
Online since: March 2010
Authors: Jun Zhao, Rui Ma, Xiao Ting Peng
Research On Intelligent Deep Drawing Technology Of Sheet Metal
Rui Ma 1, a, Jun Zhao
1,b and Xiaoting Peng2,c
1
College of Mechanical Engineering, Yanshan University, Qin huangdao 066004, China
2
State Key Laboratory of Metastable Materials Science and Technology, Yanshan University, Qin
huangdao, 066004, China
a
mar@ysu.edu.cn, bzhaojun@ysu.edu.cn, cdistancemm@yahoo.com.cn
Keywords: deep drawing; intelligent sheet metal forming; simple shape parts; sheet metal forming.
Acknowledgements Thanks to the sponsor of National Natural Science Foundation of China (No.59875074 and No.50375136).
Yang: Journal of the JSTP, Vol. 387 (34) (1993), p. 398 [3] J.
Wang: Journal of Materials Processing Technology, Vol. 166 (2005), p.387 [8] J.
Cao: Journal of Yanshan University, Vol. 22 (3) (1998), p.197 (in Chinese) [9] J.
Acknowledgements Thanks to the sponsor of National Natural Science Foundation of China (No.59875074 and No.50375136).
Yang: Journal of the JSTP, Vol. 387 (34) (1993), p. 398 [3] J.
Wang: Journal of Materials Processing Technology, Vol. 166 (2005), p.387 [8] J.
Cao: Journal of Yanshan University, Vol. 22 (3) (1998), p.197 (in Chinese) [9] J.
Online since: July 2021
Authors: Martin Nguyen, Radomír Sokolař, Oldřich Pavelka
Construction and Building Materials 34 (2012), pp. 285-295
Construction and Building Materials 34 (2012), pp. 170-178
Journal of Hazardeous Materials 173 (2010), pp. 480-486
Materials Science and Engineering. 385 (2018), pp. 1-6
Applied Clay Science,. 51 (2011), pp. 1 – 7.
Construction and Building Materials 34 (2012), pp. 170-178
Journal of Hazardeous Materials 173 (2010), pp. 480-486
Materials Science and Engineering. 385 (2018), pp. 1-6
Applied Clay Science,. 51 (2011), pp. 1 – 7.
Online since: November 2015
Authors: Catalin Andrei Tugui, Carmen Nejneru, Manuela Cristina Perju, Petrică Vizureanu, Mihai Axinte
Mangeron, No. 51, 700050, Iasi, Romania
2Technical University “Gheorghe Asachi” of Iasi-Romania, Department of Material Science,
Blvd.
Materials and Methods Base Material.
Shtansky, Advanced Technologies, materials and coatings developed in scientific-Educational Center of SHS, Galvanotechnik, 2009, pp. 1-13
[7] Jian-sheng Wang, Hui-min Meng, Hong-ying Yu, Zi-shuan Fan, Dong-bai, Characterization and wear behavior of WC-0.8Co coating on cast steel rolls by electro-spark deposition, International Journal of Minerals, Metallurgy and Materials. 16, 6 (2009) 707-713
Xiong, Microstructure and properties of TiC coating by vibrating electrospark deposition, Key Engineering Materials. (2008) 373-374
Materials and Methods Base Material.
Shtansky, Advanced Technologies, materials and coatings developed in scientific-Educational Center of SHS, Galvanotechnik, 2009, pp. 1-13
[7] Jian-sheng Wang, Hui-min Meng, Hong-ying Yu, Zi-shuan Fan, Dong-bai, Characterization and wear behavior of WC-0.8Co coating on cast steel rolls by electro-spark deposition, International Journal of Minerals, Metallurgy and Materials. 16, 6 (2009) 707-713
Xiong, Microstructure and properties of TiC coating by vibrating electrospark deposition, Key Engineering Materials. (2008) 373-374
Online since: August 2014
Authors: Xiao Wang, Chuang Huang, Yan Wei Wu, Dong Dong Meng, Hui Xia Liu
Materials and Experiments
Materials.
Memola Capece Minutolo: Journal of Materials Processing Technology, Vol. 167 (2005) No.2-3, pp.422–428
Bag: Materials Science and Engineering B, Vol. 132 (2006) No.1-2, pp.113-120
Katayama: Journal of Materials Processing Technology, Vol. 211 (2011) No.6, pp.1166-1174
Bartha, et al: Journal of Vacuum Science & Technology A, Vol.3 (1985) No.3, pp.739
Memola Capece Minutolo: Journal of Materials Processing Technology, Vol. 167 (2005) No.2-3, pp.422–428
Bag: Materials Science and Engineering B, Vol. 132 (2006) No.1-2, pp.113-120
Katayama: Journal of Materials Processing Technology, Vol. 211 (2011) No.6, pp.1166-1174
Bartha, et al: Journal of Vacuum Science & Technology A, Vol.3 (1985) No.3, pp.739
Online since: October 2012
Authors: Bin Meng, Jin Hui Peng
In microwave metallurgy process, the refractory materials are exposed both to microwave energy and the reaction materials.
These complex stringent requirements restrict the candidate range of refractory materials for microwave metallurgy, so that the refractory material only with single component hardly meets the demands for microwave metallurgy process.
Therefore, the composite refractory materials, such as corundum-mullite, were explored to be applied in microwave metallurgy.
Bulletin of Materials Science, 2009, 32, (1):1-13 [2]MacKenzie, J.
Journal of Hazardous Materials, 2009, 166: 1535-1539
These complex stringent requirements restrict the candidate range of refractory materials for microwave metallurgy, so that the refractory material only with single component hardly meets the demands for microwave metallurgy process.
Therefore, the composite refractory materials, such as corundum-mullite, were explored to be applied in microwave metallurgy.
Bulletin of Materials Science, 2009, 32, (1):1-13 [2]MacKenzie, J.
Journal of Hazardous Materials, 2009, 166: 1535-1539
Online since: August 2019
Authors: Hartati Hartati, Suryani Idris Irma, Dini Iwan, Rahmawati Nur, Ali Alimuddin
Material and Methods
Preparation extract
The plant materials were collected from West Sulawesi, Indonesia.
[6] M Rafieian, R Ansari, R Arami, et al., “Effect of Teucrium polium and Boswellia serrata extracts on cotaneus burn wound healing in Balb/C mice,” Journal of Shahrekord University of Medical Sciences, vol. 12, no. 1, (2011) 49–53
Rahimi-Madiseh et al., “Effect of Portulaca oleracea L vice versa silver sulfadiazine on burn wound healing in Balb/c mice,” Journal of Shahrekord University of Medical Sciences, vol. 13, no. 6, (2012) 92–100
Journal of Ethnopharmacology, 127 (2010) 614-619
Journal of Natural Remedies, 9 (2009) 21-26.
[6] M Rafieian, R Ansari, R Arami, et al., “Effect of Teucrium polium and Boswellia serrata extracts on cotaneus burn wound healing in Balb/C mice,” Journal of Shahrekord University of Medical Sciences, vol. 12, no. 1, (2011) 49–53
Rahimi-Madiseh et al., “Effect of Portulaca oleracea L vice versa silver sulfadiazine on burn wound healing in Balb/c mice,” Journal of Shahrekord University of Medical Sciences, vol. 13, no. 6, (2012) 92–100
Journal of Ethnopharmacology, 127 (2010) 614-619
Journal of Natural Remedies, 9 (2009) 21-26.
Online since: June 2012
Authors: Xue Gang Luo, Xiao Yan Lin, Qing Ding
Thermal decomposition characteristics of Mg (NO3)2·6H2O and MgCl2·6H2O composite as phase change material
Qing Ding1,2, a, Xuegang Luo1,2, b, Xiaoyan Lin1,2
1School of Materials Science and Engineering, Southwest University of Science and Technology, Mianyang 621010, China
2Engineering Research Center for Biomass Materials, Ministry of Education, China
a email: ddingqqing@gmail.com b lxg@swust.edu.cn
Keywords: Mg (NO3)2·6H2O; MgCl2·6H2O; decomposition; dehydration;
Abstract: The thermal decomposition characteristics of Mg (NO3)2·H2O and MgCl2·6H2O composite were studied by integrated thermal analysis.
Results show that there are five steps during the thermal decomposition of phase change material (PCM): the starting temperature of each step is 35.5 oC, 93 oC, 196 oC, 260 oC and 318 oC, respectively.
Introduction Phase change materials have attracted the intensive interest of researchers as they are employed in an increasing number of applications in recent years [1].
Most of thermal energy storage systems are based on the use of phase change materials with high storage capacity.
Kaps C.: Thermochimica Acta Vol.502 (2010), p.73 [3] Tyagi V.: Solar Energy Materials and Solar Cells Vol.92 (2008), p.891 [4] Nagano K., Ogawa K.: Applied Thermal Engineering Vol.24 (2004), p.221 [5] Huang Q.Z.: Journal of Analytical and Applied Pyrolysis Vol.91 (2011), p.159 [6] Kashani N: Magnesium Technology in the Global Age, 2006, p.81
Results show that there are five steps during the thermal decomposition of phase change material (PCM): the starting temperature of each step is 35.5 oC, 93 oC, 196 oC, 260 oC and 318 oC, respectively.
Introduction Phase change materials have attracted the intensive interest of researchers as they are employed in an increasing number of applications in recent years [1].
Most of thermal energy storage systems are based on the use of phase change materials with high storage capacity.
Kaps C.: Thermochimica Acta Vol.502 (2010), p.73 [3] Tyagi V.: Solar Energy Materials and Solar Cells Vol.92 (2008), p.891 [4] Nagano K., Ogawa K.: Applied Thermal Engineering Vol.24 (2004), p.221 [5] Huang Q.Z.: Journal of Analytical and Applied Pyrolysis Vol.91 (2011), p.159 [6] Kashani N: Magnesium Technology in the Global Age, 2006, p.81
Online since: November 2020
Authors: Vytenis Naginevicius, Vladimirs Gudakovskis, Esmeralda Styps, Rolandas Sertvytis, Viktors Gutakovskis, Eriks Gerins
The determination of these variables depends on experience and knowledge regarding the workpiece and tool materials, coolant conditions, and other factors.The determination of these operating parameters depends on experience and knowledgeregarding the workpiece and tool materials, coolant conditions, and other factors.
As the machined part material were chosen AISI 420 and AISI 304 Stainless steel.
Material: AISI 420.
Cus, et al., Adaptive controller design for feedrate maximization of machining process, Journal of Achievements in Materials and Manufacturing Engineering. 17(1-2) (2006) 237-240
Alaskar, Adaptive control program for rough turning machining processes, 6th Int'l Conference on Advances in Engineering Sciences and Applied Mathematics (ICAESAM’2016). 21-22 (2016) 18-23
As the machined part material were chosen AISI 420 and AISI 304 Stainless steel.
Material: AISI 420.
Cus, et al., Adaptive controller design for feedrate maximization of machining process, Journal of Achievements in Materials and Manufacturing Engineering. 17(1-2) (2006) 237-240
Alaskar, Adaptive control program for rough turning machining processes, 6th Int'l Conference on Advances in Engineering Sciences and Applied Mathematics (ICAESAM’2016). 21-22 (2016) 18-23