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Materials and methods This experiment uses materials such as corn.
Inlet Channel of Natural Air Exhaust Steam Water Collector door Outlet Channel of Natural Air Collector rack Dryer Materials Cover glass Heat Chamber Fin Collector Frame Figure 1.
Journal of Renewable Energy Development 1(2) (2012) 33-38
Chandrasekar, Performance of a Forced Convection Solar Drier Integrated With Gravel as Heat Storage Material For Chili Drying, Journal of Engineering Science and Technology, 4(3) (2009) 305 – 314
G., Design and Construction of Forced/Natural Convection Solar Vegetable Dryer With Heat Storage, ARPN Journal of Engineering and Applied Sciences, 7(10) (2012) 1213–1217.

Experimental Procedures Materials (Cu-11Mn-4Ni powder) The powder used for solidification in this study was Cu-11Mn-4Ni.
Takeishi: Dynamic Molding of Powder Particles at Room Temperature, Materials Science Forum. 706-709, (2012), 1955-1960 [3] T.
Takeishi, and Noboru Nakayama, Consolidation of Nd-Fe-B melt-spun ribbon by compression shearing method, Journal of applied physics 101, (2007) 09K503 [4] T.
Nakayama: Production of amorphous bulk material of an Nb15Fe77B8 magnetic alloy by the compression shearing method, Journal of Alloys and Compounds, 396, (2005) 208-211 [7] T.
Nakayama: New method for the production of bulk amorphous materials of Nb15-Fe77-B8 alloys, J.

SF0180058s07, 0140062s08, Estonian Science Foundation grants No. 8377, 8420, 8211 and 9281, Estonian Nanotechnology Competence Centre and European Science Foundation Fanas program “Nanoparma", Graduate School on Functional Materials and Technologies and EU Social Funds project 1.2.0401.09-0079.
Journal of Materials Science. 39 (2004) 6057 – 6066
Materials Letters. 60 (2006) 1833–1838
Journal of Sol-Gel Science and Tehnology. 47 (2006) 31-37
Journal of Materials Science. 33 (1998) 4697 – 4706

All materials were used as received.
Journal of Materials Processing Technology. 153.22(2004):401–407
Materials Science and Engineering A. 425.1(2006):7-14
Journal of Applied Polymer Science. 113(2009):1664-1670
Materials Science and Engineering A. 398.1(2005):180–187

Cao, “Mechanics of fracture in single point incremental forming,” Journal of Materials Processing Technology, vol. 212, no. 7, pp. 1573–1590, Jul. 2012
H. van den Boogaard, “An overview of stabilizing deformation mechanisms in incremental sheet forming,” Journal of Materials Processing Technology, vol. 209, no. 8, pp. 3688–3695, Apr. 2009
H. van den Boogaard, “Strain in Shear, and Material Behaviour in Incremental Forming,” Key Engineering Materials, vol. 344, pp. 519–526, 2007
Allwood, “The mechanics of incremental sheet forming,” Journal of Materials Processing Technology, vol. 209, no. 3, pp. 1158–1174, Feb. 2009
Bai, “Calibration and evaluation of seven fracture models,” International Journal of Mechanical Sciences, vol. 47, no. 4–5, pp. 719–743, Apr. 2005

Advanced Materials Research, 264, 1545-1550
Journal of materials processing technology, 200(1), 373-384
Advanced Materials Research, 576, 95-98
Advanced Materials Research, 264, 1102-1106
Optimization by simulated annealing. science, 220(4598), 671-680

Journal of Materials Science 35.6(2000) 1303-1313
Materials Science & Technology 27.9(2011) 1443-1447
Journal of Materials Processing Technology 178.1–3(2006) 34-38
Journal of Minerals & Materials Characterization & Engineering 10.2(2011) 127-141
Materials Science & Engineering A 528.28(2011) 8212-8217

Rashid1b, Masahiro Ohshima2c, Saowaroj Chuayjuljit3d, Azlan Ariffin1e* 1School of Materials and Mineral Resources Engineering, Engineering Campus, Universiti Sains Malaysia, Nibong Tebal, 14300 Penang, Malaysia 2Department of Chemical Engineering, Kyoto UnIversity, Nishikyo-ku, Kyoto, 615-8510, Japan 3Department of Materials Science, Faculty of Science, Chulalongkorn University, Phayathai, Bangkok 10330, Thailand aanny_ora@yahoo.com, bazura@eng.usm.my, coshima@cheme.kyoto-u.ac.jp, dschuayjuljit@yahoo.com, eazlan@eng.usm.my Keywords: waste natural rubber latex, blend, latex treatment, Abstract.
Experimental Materials.
This is due to the rigidity of PS that assists as in reinforcing materials in blends.
[4] Boondamnoen O., Ohshima M., Azura A.R., Chuayjuljit S. and Ariffin A.: Proceeding of 6th International Conference on Advanced Materials Development and Performance.
Vol. 45 (2009), p.2996-3003 [16] Charile R.B. and Ashok C.: Failure Analysis of Engineering Materials, chapter 3, published by McGraw-Hill. (2002), p. 188-207

Makinde, On the thermal decomposition of reactive materials of variable thermal conductivity and heat loss characteristics in a long pipe, Journal of Energetic Materials, 30(4) (2012) 283–298
Steinbach, Self-ignition of combustible bulk materials under various ambient conditions.
Chinyoka, Thermal decomposition analysis in a sphere of combustible materials.
Iranian Journal of Science and Technology, Transactions of Mechanical Engineering, 39, No.
Makinde, Computational analysis of CO2 emission, O2 depletion and thermal decompositionin a cylindrical pipe filled with reactive materials.

Introduction Polymeric materials are essential raw material for the manufacture of packaging and the global market has contributed to the increased this demand.
The slip agents are materials which are employed principally to adjust the friction coefficient (FOC) of the polymeric surfaces and to adjust the adhesion of these materials to other polymeric surfaces.
The nanoclay has been applied as additive of the polymeric materials [8] and as compatibilizers agents for polymers [9].
Schirrer: Journal Wear Vol. 271 (2001), p. 671
Li: Materials & Design Vol. 107 (2016), p. 171