Search results

Materials and Methods Description of dryer and material selection: The system set up is shown in Figure 1.
Oosthuizen, The design of indirect solar rice dryer”, Journal of Engineering for International Development, 2 (4) (1995) 20-27 [6] V.K.
Akolade, Development of a photovoltaic powered forced convection solar dryer, Advanced Materials Research, 62-64 (2009) 543-548 [16] R.
Mukhtar, Effect of storage temperatures on post harvest deterioration of banana and plantain (Musa spp), International Journal of Pure and Applied Sciences, 3 (2) (2009) 28-38 [19] S.
Kalogirou, Solar thermal collectors and applications, Progress in Energy and Combustion Science, 30 (2004) 231-295 [21] J.

Acknowledgement This research is supported by the National Natural Science Foundation of P.
Mazars, in: Handbook of Materials Behavior Models, edited by Jean Lemaitre, chapter, 6, Academic Press (2001)
McDowell, in: Handbook of Materials Modeling, edited by Sidney Yip, Chapter, 3, Springer (2005)
Lee: submitted to International Journal of Fracture (1987)
Pijaudier-Cabot: submitted to Journal of Engineering Mechanics (1989).

The Effect of Plasma Power on the Properties of Amorphous Silicon-Germanium Thin Films Long Gu1, a, Huidong Yang1,2,b , Bo Huang1,2,c 1 Department of Electronic Engineering, Jinan University, Guangzhou 510632, China 2 State Key Lab of Silicon Materials, Zhejiang University Hangzhou 310027, China.
The work was financially supported by The Guangdong Province and Ministry of Education of China (No.2008A090400011); The Guangdong-Hong Kong Technology Cooperation Funding Project (No.2008A011800005, No.2009205115, No.20090101-4); The Natural Science Foundation of Guangdong Province ( No.06025195, No.9151027501000076); Visiting Scholar Foundation of State Key Lab of Silicon Materials at ZhejiangUniversity( No.SKL2009-13); The Funding Project of Shenzhen Hong Kong Innovation Circle.
Ikeda, et al, Hydrogenated microcrystalline silicon germanium: A bottom cell material for amorphous silicon-based tandem solar cells, Appl.
Matsui,et al, Microcrystalline sillicon-germanium alloys for solar cellapplication: Growth and material properties, Journal of Non-CrystallineSolids,352,p.1255-1258,(2006)
[10] Huidong Yang: ‘Modulation Effect of Plasma Power on μs-Si:H thin film and its deposition process with VHF-PECVD technique’ Journal of Optoelectronics Laser,Vol.18,No.5,2007(in Chinese)

She will received the master’s degree in materials science from Beihang University, Beijing, 2013.
Journal of Electronic Materials.1999, 28(11):1231-1237 [9] Zhang Wei, Wang Chunqing, Yan Bohan.
Rare Metal Materials and Engineering. 2006, 35(7):1143-1145 [10] Yang Anheng, Xie Hongchao.
Welding Equipment and materials. 2005,34(4): 49-51 [12] Pan Hui, Sun Ji-Sheng, Liu Xiao-fang.
Journal of Aeronautical Materials. 2000, 20(4):26-29

Figure 4 Simulation results Conclusion To solve the problem of large data processing during the process of defect detection, aiming at the characteristics of defect signals of measured materials, we developed an FPGA-based real-time data processing technology that is suitable for surface defect detection of materials. dedicated hardware FPGA is used in the lower layer to preprocess the image; dynamic threshold is used to determine the scope of defects and to extract defect data and package; under the premise of reserving complete brightness of the defects, the uploaded data is compressed to the maximum to reduce data processing pressure of the upper computer data so that the testing speed and accuracy of the whole device are enhanced.
Acknowledgment The project is supported by Natural Science Foundation of Shandong Province (NO. 2010ZRA07002).
“Development of Flat Field Holographic Concave Gratings with High-resolution”, Journal of Optoelectronics, Laser, Vol 17, Jul. 2006, pp. 828-831
The Second International Conference on Information and Computing Science, No. 2, 2009, pp.373-375
The Second International Conference on Information and Computing Science, No. 2, 2009, pp.207-210.

Materials Materials are shown in Table 1.And the material of base layer and clad layer are 16MnIII and S30408, respectively.
Table1 Materials Parameter Cylinder Tube sheet Tube Material Q245R 16MnIII+ S30408 S30408 Physical Models Structural parameters of models are listed in Table 2.
Material properties of heat exchanger at design conditions are listed in Table 3 Table 3 Data of material characteristics at design condition Material Q245R 16MnIII S30408 E/Pa 1.95e11 1.94e11 1.02e11 v 0.3 0.3 0.31 /m(m·°C )-1 1.18e-5 1.18e-5 1.70-5 []/MPa 138.2 187.8 135.6 /W(m·°C )-1 50.6 50.6 16.5 Grid division.
Jin, Application of composite pipe plate structure in heat exchanger design, Journal of Chemical Industry & Engineering, 5(2000) 26-27
Leea, et al., Effects of shielding gases on the microstructure and localized corrosion of tube-to-tube sheet welds of super austenitic stainless steel, Corrosion Science, 8( 2011) 2611-2618

Materials Park (OH): ASM International, 2002
[6] Buchhagen P, Bell T: Computational Materials Science, Vol 7, 1996, p. 228
[7] Hirsch TK, Rocha ADS, Ramos FD, Strohaecker TR: Metallurgical and Materials Transactions A, Vol 35, 2004, p. 3523
[9] Leroy C, Michel H, Gantois M: Journal of Materials Science, Vol 21, 1986, p.3467
[12] Jegou S, Kubler R, Barrallier L : Advanced Materials Research, Vol 89-91, 2010, p. 256.

As the transmutation products of H and He will induce irradiation damage, which may change the microstructure and mechanical properties of structural materials, it is necessary to study on this issue .
Though the effects of single H or He irradiation damage on the materials’ properties have been studied for many years[5-8], there are few reports of He/H ion co-implantation effect on ODS ferritic steels [9,10].
Zhang, Y.H.Dou, Materials Letters 65 (2011) 1672–1674 [4] S.
Ohnuki Materials Science and Engineering A 510–511 (2009) 115–120 [5] Y.P.Zeng, F.R.
Journal of Physics: Conference Series 262 (2011) 012053 [14] T Ishizaki , Q Xu , T Yoshiie , et al.

Those characteristics are desired when materials are submitted to deformation by creep.
Cairney: Materials Science and Engineering A Vol. 527 (29-30), (2010), p. 7770
Hagel Superalloys II: High Temperature Materials for Aerospace and Industrial Power.
ASM International, The Materials Information Society. 1996 [5] C.M.
Tai: Materials Science and Engineering A Vol. 510-511(2009), p. 289.

Define the material parameters.
Click "Apply / edit material, material selection No. 45 just material parameters default.
Click "Apply / edit material" definition of material parameters.
Acknowledgement This work is supported by the Natural Science Foundation Key Project in Anhui Education Department (KJ2011A094,KJ2009A028).
Journal of Magnetism and Magnetic Materials. 2006, 301(2): 532-540