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Introduction The use of composite materials is widely increasing in applications due to a number of advantages over other materials.
References [1] Jones, R., 1999, Mechanics of composite materials, Taylor & Francis Inc
G. , 2004, "Strain rate effects on the mechanical properties of polymer composite materials," Journal of Applied Polymer Science, 94, pp. 296–301
J., 2007, "Investigation of strain-rate effects in self-reinforced polypropylene composites," Journal of Composite Materials, 41(20), pp. 2457-2470
-M., Werner, B.T., Fenner, J.S., "Mechanical behaviour and failure criteria of comosite materials under static and dynamic loading," Proc. 50th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference.

References [1] Zhao-Dan, Ma Chunyan: Wood composite materials.
Shanghai building materials (2002)
[2] Hao Yua kai, Xiao Jiayu:High-performance composite materials science.
[6] Ouyang Guoen, Ou Guorong:Composite Materials Testing Technology.
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TiO2/tourmaline composite photocatalyst materials were fabricated mainly by the sol-gel technique.
Results and discussion 3.1 Natural electrical polarity of TiO2/tourmaline composite photocatalyst materials Fig.1 were the images of TiO2/tourmaline composite photocatalyst materials by SEM, and the TiO2/tourmaline composite photocatalyst materials had been calcinated at 400℃,500℃,600℃and 700℃ for 3h separately, under bombardment for 10s by electron beam, scan accelerating voltage 25.0kV.
Conclusion TiO2/tourmaline composite photocatalyst materials have natural electrical polarity, especially after 600℃ heat treatment.
Acknowledgements This work was partially financially supported by the National Science Foundation of China (No 50272062), and the National High Technology Development Program of China (No.2001AA322050), and the Natural Science Foundation of Hebei Province, China (No.503067) References [1] T Nakamura, T Kubo.
Journals of material science letters, Vol.22(2003), p.1503~1509

There have been reported by several researches that zeolite can be synthesized from many raw materials which contain high amount of silica and alumina such as clay, bauxite and incinerated ash.
The products were washed until they were neutral and dried. 2.2 Materials Characterization The chemical composition of water treatment sludge was performed by XRF.
Sagala, Synthesis of Na-zeolite on the Basis of Dual Cation/Anion Exchange Capacity with Regeneration Capabilities, Journal of Materials Sciences and Applications, 2 (2016) 20-24
Kumar, Microstructural and morphological evolution of fly ash based geopolymers, Construction and Building Materials, 111 (2016) 758-768
Sahu, Kinetic and isotherm studies of cadmium adsorption on manganese nodule residue, Journal of Hazardous Materials, 137 (2006) 915-924.

Selke, An overview of polylactides as packaging materials.
Macromolecular Materials and Engineering, 2012: p. 75-84
Materials Letters, 2006. 60(11): p. 1331-1333
Journal of membrane science, in press, 2012(0)
Journal of membrane science, 2011

Advanced Energy Materials, 5(3), 1400993
Advanced materials, 28(15), 2888-2895
Nature materials, 16(5), 572-579
Materials express, 2(3), 197-212
ACS Applied Energy Materials

One approach to improving the performance of Fe0 towards specific contaminants is to create core-shell composites with different materials [14,16].
Methodology Materials.
Chang, “Fabrication of magnetic lignosulfonate using ultrasonic-assisted in situ synthesis for efficient removal of Cr (VI) and rhodamine B from wastewater,” Journal of Hazardous Materials, vol. 375, pp. 174–181, 2019
Zhang, “Recent advances of carbon-based nano zero valent iron for heavy metals remediation in soil and water: A critical review,” Journal of Hazardous Materials, vol. 426, p. 127993, 2022
Mak, “Lab-scale simulation of the fate and transport of nano zero-valent iron in subsurface environments: Aggregation, sedimentation, and contaminant desorption,” Journal of Hazardous Materials, vol. 227-228, pp. 118–125, 2012

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Serindag: Journal of Achievements in Materials and Manufacturing Engineering, Vol. 30 No 2 (2008), p. 151
Vilaca: Material science and engineering A Vol. 528 (2010) p. 5592

Adaptive Simulation of Automated Guided Vehicle Systems Using Multi Agent Based Approach for Supplying Materials Angéla Rinkács1, a, András Gyimesi2,b and PhD Gábor Bohács3,c 1PhD Student, Department of Material Handling and Logistics Systems, Budapest University of Technology and Economics, Hungary 1Assistant Lecturer, Department of Material Handling and Logistics Systems, Budapest University of Technology and Economics, Hungary 3 Head of Department, Department of Material Handling and Logistics Systems, Budapest University of Technology and Economics, Hungary 1,2,3H-1111 Budapest, Bertalan L.u. 7-9.
aAngela.Rinkacs@logisztika.bme.hu, bAndras.Gyimesi@logisztika.bme.hu, cGabor.Bohacs@logisztika.bme.hu Keywords: AGV, Logistics, Simulation, Materials Handling.
One main application area for AGVs is the intralogistics or manufacturing logistics, where the vehicles are mainly used for transporting raw materials, half-ready parts and ready products.
References [1] Le-Anh, T., De Koster, M.B.M.: A review of design and control of automated guided vehicle systems, European Journal of Operational Research 171 (2006) 1–23
Kostal P.: General Process Control for Intelligent Systems, World Academy of Science, Engineering and Technology 77 2013

Journal of Magnetism and Magnetic Materials 327 (2013) 151–158
Journal of Magnetism and Magnetic Materials 302 (2006) 429–435
Journal of Magnetism and Magnetic Materials 280 (2004) 214–220
Journal of Materials Science: Materials in Electronics, vol. 20, no. 5, pp. 408–417, 2009
Journal of Materials Science: Materials in Electronics, 2018. https://doi.org/10.1007/s10854-018-9535-9