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On Experimental Thermal Analysis of BMC Mensolite 3100 Aging Pavol Koštial1,a, Jozef Vlček1,b, Zora Koštialová Jančíková1,c , Ivan Ružiak2,d, Milada Gajtanská2,e, Marek Velička1,f*, Ondrej Bošák3,g and Hana Špačková1,h 1Faculty of Materials Science and Technology, VŠB-Technical University of Ostrava, 17. listopadu 15/2172, 70800 Ostrava, Czech Republic 2Faculty of Wood Sciences and Technology, T.G.
Specific properties of materials demand a large spectrum of measuring methods suitable for thermal parameters measurements.
In case that heat is delivered in identical way to two different materials and the airflow speed around the sample is invariable, it could be supposed that the heat transfer coefficient h for two different types of materials would be approximately the same.
Hlinka, On Experimental Thermal Analysis of Solid Materials, Measurement Science Review, 14(6), 317-322. (2014) [3] S.
Kršková, Experimental method for complex thermo-mechanical material analysis, International Journal of Thermophysics, 31(3), 630-636. (2010)

Sieniawski, "The effect of microstructure on mechanical properties of two-phase titanium alloys," Journal of Materials Processing Technology, vol. 133, pp. 84-89, 2003
Shin, "Thermal and mechanical modeling analysis of laser-assisted micro-milling of difficult-to-machine alloys," Journal of Materials Processing Technology, vol. 212, pp. 601-613, 2012
Celaya, "Plasma assisted milling of heat resistant super alloys," Journal of Manufacturing Science and Engineering Transaction of ASME, vol. 126, pp. 274-258, 2004
Koksal, "Evaluation of wear mechanisms of coated carbide tools when face milling titanium alloy," Journal of Materials Processing Technology, vol. 99, pp. 266-274, 2000
Higuchi, "Development of ultra-fine-grain binderless cBN tool for precision cutting of ferrous materials," Journal of Materials Processing Technology, vol. 209, pp. 5646-5652, 2009

Dong1 and *C.J.Choi2 1 State Key Laboratory for Materials Modification by Laser, Ion and Electron Beams, and School of Materials Science and Engineering, Dalian University of Technology (DUT), Dalian, Liaoning, 116024, China 2 Korea Institute of Machinery and Materials, 66 Sangnam-Dong, Changwon, Kyungnam 641-010, Korea *E-mail address: dongxl@dlut.edu.cn (X.L.
As an inspiration, we found this kind of nanocapsules with a dielectric shell and a ferromagnetic core are very promising for new EM wave absorption materials.
Recent studies on carbon-containing materials, such as carbon nanotubes (CNTs) [5-6], carbon nanofibers (CNFs) [7], have sparked a new arena for developing effective microwave absorption/shielding materials since their excellent EM wave absorption properties.
Yang, Journal of Materials Science 33, 1915 (1998)
Choi, Journal of Physics D: Applied Physics,2007, submitted

Feedstock materials were submicrocrystalline powders of dysprosia Dy2O3 and zirconia ZrO2.
The obtained results showed that these materials are very attractive for the top ceramic materials for thermal barrier systems [8-13].
Acknowledgments This work was supported by Institute of Materials Science of Silesian University of Technology, as a part of Statutory Research no BK232/RM3/2014.
[13] Maloney M.J., Thermal barrier coating systems and materials.
[15] Cao X., Ma Z., Liu Y., Du Z., Zheng K., Rare Metal Materials and Engineering 42 (2013) 1134

Narasimha Rao, "Optical properties of pure and doped PMMA-CO-P4VPNO polymer films", Materials Letters 57(30), 4678-4683 (2003)
Ryo Oono, "Distribution of carbon black in SBR", Journal of Applied Polymer Science, 21(7), 1743-1749 (1977)
Kajiwara, "Electrical properties of poly(n-butylamino) (di-allylamino) phosphazene", Journal of Material Science, 33(11), 2955-2959 (1998)
Hafez, "Physico-chemical stability of PVA films doped with Mn2+ ions against weathering conditions", The Arab Journal for Science and Engineering 34 (1A), 13-26 (2009)
Ayesh, "Electrical and optical characterization of PMMA doped with Y0.0025Si0.025 Ba0.9725(Ti(0.9)Sn0.1)O3 ceramic", Chinese Journal of Polymer Science 28(4), 537-546 (2010)

Alexandre, Materials Science and Engineering R. 63 (2009) 100
Butler, Fire and materials. 24 (2000) 277
Harris, Journal of Applied Polymer Science. 87 (2003) 1541
Ebeoglugil, Journal of Applied Polymer Science. 105 (2007) 3747
Levchik, Journal of Fire Science. 26 (2008) 243.

Study on high-density-copper grain-refining Cu-W Composites Dunqiang Tan1,a, Qiang Chen1,b, Fangxin Yu1,cand Wenxian Li2,d 1School of Material Science and Engineering, Nanchang University, Nanchang Jiangxi, 330031, China 2School of Materials Science and Engineering, Central South University, Changsha,Hunan, 410083, China acntdunqiang@yahoo.com.cn, bbaixkj-2008@163.com, cyfx11@263.net, dvictor2008@126.com Keywords: high-density-copper Cu-W, Co-reduction, sintering temperature, compacting pressure Abstract.
The enhancement of capillary force did good for particle rearrangement which led to form compact materials [23].
References [1] Zhixiang Li, Xiaoqing Yang: Materials of Engineering, Vol. 8, issue 32, 53-55, 2005, In Chinese [2] Wei Chen, Yonggeng Kuang, Wuping Zhou: Rare Metal Materials and Engineering, Vol.33, issue l, 11-14, 2004, In Chinese [3] Yunping Li, Xianhui Qu, Behua Duan: Cemented Carbide, Vol.18, issue 4, 232-236, 2001, In Chinese [4] Bregel T, Krauss-Vogt W, Michal R, et al: IEEE Transactions on Components Hybrids and Manufacturing Technology, Vol.14, issue1, 8-13,1991 [5] Donaldson A L, Kristiansen M: 7th IEEE ,Pulsed Power Conference, 83-86, 1989 [6] Soffa W A, Laughlin D E: Program In Material Science, Vol.49, 347-366, 2004 [7] Kim D G, Kim G S, Oh S T, et al: Materials Letters, Vol.58, 57-58, 2004 [8] Yang B, German R M: International Journal of Powder Metallurgy, Vol.33, issue 4, 55-61, 1997 [9] Zheng Li: Foreign Weapon News, issue 6, 15-16, 2000 [10] Held.
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Tao, Zuping Wang, Ningxiang Fang, et al: Powder Metallurgy Technology, Vol.20, issue 1,49-51,2002, In Chinese [20] Sebastian K V, Tendolker G S: International Journal Powder Metal and Powder Technology, issue1, 45-53, 1979 [21] Lee J S, Kim T H: Nanostructured Materials, issue 6, 691-694, 1995 [22] Shunhua Cao, Xiping Lin, Jiongyi Li: The Chinese Journal of Nonferrous Metals, Vol.15, issue 2, 248-253, 2005, In Chinese [23] Dongdong Gu, Yifu Shen: Acta Metallurgica Sinica, Vol.45, issue1, 113-118, 2009 [24] Johnson J L, Brezovsky J J, German R M: Metallurgical and Materials Transactions A, Vol.36, issue 6, 1557-1565, 2005 [25] Johnson J L, Brezovsky J J, German R M: Metallurgical and Materials Transactions A, Vol.36, issue 10, 2807-2814, 2005

The principle of the choice of materials depends on the task.
So, for example, compositions based on mineral raw materials are known.
Series: Earth and Environmental Science, 87.8 (2017) 082047
Gabarrell, Environmental assessment of façade-building systems and thermal insulation materials for different climatic conditions Journal of Cleaner Production, 113 (2015) 102-113
Zhang, Novel application of glass fibers recovered from waste printed circuit boards as sound and thermal insulation material Journal of materials engineering and performance, 22.10 (2013) 3140-3146

Experimental This section consists of materials, preparation of CS/NR composites, and characterization method including degradation test in acrylic degradation box, thermal aging, mechanical test, scanning electron microscopy (SEM), and thermogravimetric analysis (TGA). 2.1 Materials.
Sukhlaaied, Effect of chitosan content on gel content of epoxized natural rubber grafted with chitosan in latex form, Materials Science and Engineering C 33 (2013) 1041-1047
Advances in Materials Science and Engineering. (2013) 1-7
Rao, Studies on the Interfacial Interaction in Natural Rubber Latex/Chitosan Blends, Journal of Adhesion Science and Technology 26 (2012) 793–812
New route to polymeric materials derived from chitosan and natural rubber.

Moreover, PMMA is a versatile material that has been used in a wide range of fields and applications as a substitute for glass, medical technologies, building materials, billboards, implants, and other aesthetic materials.
This result set the foundation for the processing of other materials by employing the same method using a CO2 laser.
(3) Where A is the material absorption rate, R is the material reflectivity, Nr represents the real refractive index of the materials, and Ni represents the imaginary refractive index of the materials.
The original light transmittance of the PMMA materials is 92%.
Hennemann, Influence of CO2 laser radiation on the surface properties of poly(ether ether ketone), Journal of Applied Polymer Science. 64 (1997) 1091-1096