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Online since: January 2010
Authors: Tan Li
Table 3 Proportion of Manufacturing Gross Production
City
GDP(Hundred
Million Yuan)
Scale industrial
gross production
(Hundred Million
Yuan)
Manufacturing
gross production
(Hundred Million
Yuan)
Proportion of
manufacturing to
the whole industry
( %)
Suzhou 5700 15950 15731.03 98.6
Wuxi 3858 8863.28 8725.48 98.4
Changzhou 1880 4253.9 4189.96 98.5
Source: Source: �ational Economic and Social Development Statistical Bulletin of Suzhou, Wuxi
and Changzhou in 2007
Table 4 Proportions of the Top Five Fields in Suzhou, Wuxi and Changzhou's Manufacturing
Industry to the second industry as a whole
Suzhou Wuxi Changzhou
Communication Equipment, Computers and Other
Electronic Equipment Production[%]
33.17 11.73 /
Textile Industry[%] 9.97 10.75 13.4
Smelting and Pressing of Ferrous Metals[%] 8.52 19.1 8.98
Electric Equipment and Machinery[%] 6.18 6.63 9.49
Raw Chemical Materials and Chemical Products[%] 5.87 8.16 10.74
General-purpose
This Project is supported by Zhejiang Social Science Planning Key Project (08HZC306Z) and Jiangsu Philosophy and Social Science Research Project in Colleges and Universities (05SJD790063).
Li: Journal of Changzhou Institute of Technology (2007) No.5, p.65-68 [4]Z.X.
This Project is supported by Zhejiang Social Science Planning Key Project (08HZC306Z) and Jiangsu Philosophy and Social Science Research Project in Colleges and Universities (05SJD790063).
Li: Journal of Changzhou Institute of Technology (2007) No.5, p.65-68 [4]Z.X.
Online since: August 2011
Authors: Run Yang Zhong, Chang Hong Liu, Yi Er Yan, Xiao Hu
E7 will be trigged that logistic operator should deliver other materials for him/her to process.
Acknowledgements This work was financially supported by the Young Talent Program of Guangzhou University , PFund supported by the Young Talent Program of Guangzhou University, and the Science-technology Plan Projects of Guangdong province(2009B060700124) h.D.
Initial Programs Foundation of Guangzhou University and the Science-technology Plan Projects of Guangdong Province(2009B060700124).
The VLDB Journal, 2009. 18(4): p. 913-931
Acknowledgements This work was financially supported by the Young Talent Program of Guangzhou University , PFund supported by the Young Talent Program of Guangzhou University, and the Science-technology Plan Projects of Guangdong province(2009B060700124) h.D.
Initial Programs Foundation of Guangzhou University and the Science-technology Plan Projects of Guangdong Province(2009B060700124).
The VLDB Journal, 2009. 18(4): p. 913-931
Online since: May 2011
Authors: You Bao Wang, Nan Nan Wang, Dan Wu
Research on Effect of Copper on Chlorophytum Comosum-soil System
Youbao Wanga, Nannan Wangb and Dan Wuc
College of Life Sciences, Anhui Normal University, Wuhu, Anhui, 241000, China
awybzl@tom.com, bwnn174351691@126.com, cwudan_1003@yahoo.com.cn
Keywords: Chlorophytum comosum, Copper, Cu-accumulator, Soil enzyme, Recovering.
Materials and Methods Cultivation.
Acknowledgements The author acknowledges the financial support from the National Natural Science Foundation of China (No. 31070401), the Key Foundation of Education Department of Anhui Province (No.
References [1] Tuyler G: Plant Soil Vol. 41 (1974), p. 303 [2] Romanowska E, Wróblewska B, Drozak A, Zienkiewicz M and Siedlecka M: Plant Biology Vol. 52 (2008), p. 80 [3] Seregin I V and Kozhevnikova A D: Russian Journal of Plant Physiology Vol. 53 (2006), p. 257 [4] Baker AJM and Brooks RR: Biorecovery Vol. 1 (1989), p. 81 [5] Hemndez-Apaolaza L, Gasco A M, Gasco J M and Guerrero F: Bioresource Technology Vol. 96 (2005), p. 125 [6] Roberts BR, Kohorst SD, Decker HF and Yaussy D: Environ Manage Vol. 19 (1995), p. 735 [7] Tanhan MKP, Pokethitiyook P and Chaiyarat R: Chemosphere Vol. 68 (2007), p. 323 [8] Baker AJM, Reeves RD and Hajar ASM: New Phytologist Vol. 127 (1994), p. 61 [9] Kidd PS, Díez J and Martínez CM: Plant Soil Vol. 258 (2004), p. 189 [10] Mench M and Martin E: Plant Soil Vol. 132 (1991), p. 187 [11] Baker AJM: J Plant Nutr Vol. 8 (1981), p. 643 [12] Hui Xu and Yinlong Zhang: Pollution Control Technology Vol. 22 (2009), p. 103
Materials and Methods Cultivation.
Acknowledgements The author acknowledges the financial support from the National Natural Science Foundation of China (No. 31070401), the Key Foundation of Education Department of Anhui Province (No.
References [1] Tuyler G: Plant Soil Vol. 41 (1974), p. 303 [2] Romanowska E, Wróblewska B, Drozak A, Zienkiewicz M and Siedlecka M: Plant Biology Vol. 52 (2008), p. 80 [3] Seregin I V and Kozhevnikova A D: Russian Journal of Plant Physiology Vol. 53 (2006), p. 257 [4] Baker AJM and Brooks RR: Biorecovery Vol. 1 (1989), p. 81 [5] Hemndez-Apaolaza L, Gasco A M, Gasco J M and Guerrero F: Bioresource Technology Vol. 96 (2005), p. 125 [6] Roberts BR, Kohorst SD, Decker HF and Yaussy D: Environ Manage Vol. 19 (1995), p. 735 [7] Tanhan MKP, Pokethitiyook P and Chaiyarat R: Chemosphere Vol. 68 (2007), p. 323 [8] Baker AJM, Reeves RD and Hajar ASM: New Phytologist Vol. 127 (1994), p. 61 [9] Kidd PS, Díez J and Martínez CM: Plant Soil Vol. 258 (2004), p. 189 [10] Mench M and Martin E: Plant Soil Vol. 132 (1991), p. 187 [11] Baker AJM: J Plant Nutr Vol. 8 (1981), p. 643 [12] Hui Xu and Yinlong Zhang: Pollution Control Technology Vol. 22 (2009), p. 103
Online since: September 2013
Authors: Da Ping Xia, Xiao Lei Liu
Analysis of influence factors and degree for bio-methane generation
Daping Xia1, a, Xiaolei Liu2,b
1School of Energy Science and Engineering, Henan Polytechnic University, Jiaozuo, Henan China
2School of Energy Science and Engineering, Henan Polytechnic University, Jiaozuo, Henan China
a569689819@qq.com, b1406519416@qq.com
Keywords: bio-methane influence factors simulate analytic hierarchy process
Abstract: Henan Yima low rank coal is used to simulate the formation condition of coal biogenic methane in this paper.
Simulation experiment of bio-methane generation Materials and medium of experimental.
Journal of China coal society, 2011, 36(08):1302-1305.
Simulation experiment of bio-methane generation Materials and medium of experimental.
Journal of China coal society, 2011, 36(08):1302-1305.
Online since: September 2011
Authors: Xue Feng He, Wei Dong Lei, Rui Chen
Conceptual UDEC model and basic properties of the rock material
A conceptual UDEC model is established as shown in Fig. 1 for the cases of 1-D wave propagation in an intact rock, across single rock joint and multiple parallel rock joints, where the length in the x-direction is 400 m, and the height in the y-direction is 2 m.
Table 1 Mechanical properties and wave propagation velocity in the rock Properties Value Density (ρ) (kg/m3) 2650 Bulk Modulus (K) (GPa) 44 Shear Modulus (G) (GPa) 39 Velocity of shear wave (m/s) 3830 Fig. 1 The conceptual UDEC model for cases of 1-D wave propagation in an intact rock, through single rock joint and multiple parallel rock joints 1-D wave propagation in an elastic medium According to the elastic wave theory, a 1-D planer elastic wave propagates in an ideally elastic medium without wave attenuation (no material and geometrical damping).
Acknowledgements This work was financially supported by the National Science Foundation of China (51078112 ), the Guangdong Natural Science Foundations (8151805705000001 and 9451805707003007).
Cook: Journal of Geophysical Research, Vol. 95, No.
Table 1 Mechanical properties and wave propagation velocity in the rock Properties Value Density (ρ) (kg/m3) 2650 Bulk Modulus (K) (GPa) 44 Shear Modulus (G) (GPa) 39 Velocity of shear wave (m/s) 3830 Fig. 1 The conceptual UDEC model for cases of 1-D wave propagation in an intact rock, through single rock joint and multiple parallel rock joints 1-D wave propagation in an elastic medium According to the elastic wave theory, a 1-D planer elastic wave propagates in an ideally elastic medium without wave attenuation (no material and geometrical damping).
Acknowledgements This work was financially supported by the National Science Foundation of China (51078112 ), the Guangdong Natural Science Foundations (8151805705000001 and 9451805707003007).
Cook: Journal of Geophysical Research, Vol. 95, No.
Online since: December 2013
Authors: Yong Cheng Guo, Jin Long Guo
Fig. 4 The view of the Shuibuya Project Fig. 5 The material yard slope of Sanliping Fig. 6 The view of Qianchang landslide
The Material Yard Slope.
Acknowledgments The research has been supported in part by National Natural Science Foundation of China (No.51079077, 51279091), State Key Development Program for Basic Research of China (No. 2012CB426502), Science Foundation of China Three Gorges University (KJ2013B004).
Chinese Journal of rock mechanics and engineering,2004,23(7):1078-1081
Acknowledgments The research has been supported in part by National Natural Science Foundation of China (No.51079077, 51279091), State Key Development Program for Basic Research of China (No. 2012CB426502), Science Foundation of China Three Gorges University (KJ2013B004).
Chinese Journal of rock mechanics and engineering,2004,23(7):1078-1081
Online since: February 2014
Authors: Wei Shun Wang, Qing Zhang, Hong Liang Ma, Cheng Dong Hong, Jin Liang Wang, Guang Yong Bai, Yin Feng Liu
Brief introduction of a large turning table
With the development of the society and the progress of science and technology, modern large-scale projects demand more and more large parts, this will inevitably require to improve the machining capacity.
Traditional analytical calculation method basing on mechanics of materials and elastic mechanics needs to simplify the primary structure, applied force and restrained condition, the calculation accuracy and result often are far apart from the actual situation[7].
Acknowledgments This work was supported by Major national science and technology projects(2009ZX04002-021).
Journal of Hubei Polytechnic University, issue 3, Volume 11, September 1996, p.50-53
Traditional analytical calculation method basing on mechanics of materials and elastic mechanics needs to simplify the primary structure, applied force and restrained condition, the calculation accuracy and result often are far apart from the actual situation[7].
Acknowledgments This work was supported by Major national science and technology projects(2009ZX04002-021).
Journal of Hubei Polytechnic University, issue 3, Volume 11, September 1996, p.50-53
Online since: December 2012
Authors: Yan Chen, Wen Yu Zhang
Table 4 shows that the evaluation result of “logistics management” is “bad”, so, the rationality of materials in the training should be improved in the follow-up work.
Geographical Information Science, 2003, 9(2):7-78
Wuhan University Journal(Philosophy & Social Sciences), 60(3):455- 460, 2007
Geographical Information Science, 2003, 9(2):7-78
Wuhan University Journal(Philosophy & Social Sciences), 60(3):455- 460, 2007
Online since: May 2011
Authors: Ni Zhao, Xun Li
A Communication Channel Unblocked Reliability Model
under Random Conditions
ZHAO Ni1, a and LI Xun2, b
1Luoyang Institute of Science and Technology, Luoyang, China
2Henan University of Science and Technology, Luoyang, China
achewchew@yeah.net, blixun305@163.com
Keywords: communication requirements; randomness; reliability; congestion probability
Abstract.
The minus change may be caused by inaccuracy of computation itself from establishment of statistical materials, so it can be seen as determined effect.
X.: Transport Congestion Protocol Based on Congestion-probability Prediction over Wired/Wireless Hybrid Networks, Journal of Chinese Computer Systems, vol. 29, 2008, pp. 1776-1781
The minus change may be caused by inaccuracy of computation itself from establishment of statistical materials, so it can be seen as determined effect.
X.: Transport Congestion Protocol Based on Congestion-probability Prediction over Wired/Wireless Hybrid Networks, Journal of Chinese Computer Systems, vol. 29, 2008, pp. 1776-1781
Online since: March 2016
Authors: Azizah Hanom Ahmad, N. Hassan
Conductivity and FTIR Studies of NaI–Na3PO4–PLL Electrolyte for Solid State Batteries
N.Hassan1,2,a and A.H.Ahmad1,2,b*
1 Faculty of Applied Sciences, Universiti Teknologi MARA, 40450 Shah Alam,
Selangor D.E., Malaysia
2 Institute of Science, Universiti Teknologi MARA, 40450, Shah Alam, Selangor D.E., Malaysia
aazmi_xxx90@yahoo.com, bazizahanom@salam.uitm.edu.my
Keywords: Poly(L–Leucine)–1,3–diamino propane; Sodium solid electrolyte; Ionic conductivity; Sodium Iodide; Sodium Phosphate; Solid state reaction.
However, iodide based materials are hygroscopic in nature and compounds such as ortho-oxosalts usually added into these iodides–containing systems to increase the stability against atmospheric attack as well as to enhance the electrical conductivity [4].
Munichandraiah, Solid-state rechargeable magnesium cell with poly (vinylidenefluoride)-magnesium triflate gel polymer electrolyte, Journal of Power Sources. 102 (2001) 46-54
However, iodide based materials are hygroscopic in nature and compounds such as ortho-oxosalts usually added into these iodides–containing systems to increase the stability against atmospheric attack as well as to enhance the electrical conductivity [4].
Munichandraiah, Solid-state rechargeable magnesium cell with poly (vinylidenefluoride)-magnesium triflate gel polymer electrolyte, Journal of Power Sources. 102 (2001) 46-54