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Online since: October 2019
Authors: Hoang Le Tuan Anh, Huynh Thi Kieu Linh, Anh Quoc Ngo, Tri Nhut Pham, Tri Duc Lam, Tran Quoc Toan
Table 1.
References [1] G.I.
Food Chem. 139 (2013) 1–8
Lam) grown in Lam Dong province, Vietnam, IOP Conference Series: Materials Science and Engineering, 479 (2019) 012012 [11] H.
Food Qual. (2018) 1–13
References [1] G.I.
Food Chem. 139 (2013) 1–8
Lam) grown in Lam Dong province, Vietnam, IOP Conference Series: Materials Science and Engineering, 479 (2019) 012012 [11] H.
Food Qual. (2018) 1–13
Online since: April 2013
Authors: Lech Czarnecki
CONFUCIUS, 551-479 BC
Abstract.
The big idea – by definition [1] – is when existing ideas come together in new ways.
It took a quarter of century since Brundtland’s concept until an adequate regulation has been implemented (Table 1).
Table 1 Sustainable construction: from concept to European Construction Product Regulation, CPR Concept: G.H.
References [1] Information on www.biggerbrains.com [2] Y.
The big idea – by definition [1] – is when existing ideas come together in new ways.
It took a quarter of century since Brundtland’s concept until an adequate regulation has been implemented (Table 1).
Table 1 Sustainable construction: from concept to European Construction Product Regulation, CPR Concept: G.H.
References [1] Information on www.biggerbrains.com [2] Y.
Online since: September 2019
Authors: Ranita Lee, S.A. Vologzhanina, Sergej M. Bobrovskij, Boris S. Ermakov, Aleksey A. Lukyanov
References
[1] N.M.
Metal Science and Heat Treatment, 58(1), 40-45. doi:10.1007/s11041-016-9962-2 [20] Mikhailov, V.
Metal Science and Heat Treatment, 58(1), 46-50. doi:10.1007/s11041-016-9963-1 [21] Velichko, O.
Metal Science and Heat Treatment, 58(7-8), 479-482. doi:10.1007/s11041-016-0039-z [26] Kolbasnikov, N.
Metal Science and Heat Treatment, 60(1-2), 24-31. doi:10.1007/s11041-018-0235-0
Metal Science and Heat Treatment, 58(1), 40-45. doi:10.1007/s11041-016-9962-2 [20] Mikhailov, V.
Metal Science and Heat Treatment, 58(1), 46-50. doi:10.1007/s11041-016-9963-1 [21] Velichko, O.
Metal Science and Heat Treatment, 58(7-8), 479-482. doi:10.1007/s11041-016-0039-z [26] Kolbasnikov, N.
Metal Science and Heat Treatment, 60(1-2), 24-31. doi:10.1007/s11041-018-0235-0
Online since: March 2016
Authors: Lin Xu, Yan Qing Qin, Jun Zong Feng, Jian Feng, Yong Gang Jiang
Besides, the thermal conductivity of ST3 at room temperature is up to 0.03257 W·m-1·K-1.
The thermal conductivity of ST3 at room temperature is 0.03257 W·m-1·K-1.
The thermal conductivity of ST3 at room temperature is 0.03257 W·m-1·K-1.
References [1] T.
Technol. 30 (1) (1996) 41-45
The thermal conductivity of ST3 at room temperature is 0.03257 W·m-1·K-1.
The thermal conductivity of ST3 at room temperature is 0.03257 W·m-1·K-1.
References [1] T.
Technol. 30 (1) (1996) 41-45
Online since: May 2020
Authors: Fang Po Li, Bin Zhang, Zhi Wei Zhang
Chemical Composition Analysis
The chemical composition test results of X70-X100 are shown in Table 1.
Table 1 Chemical composition of material.
(a) (b) (d) (c) Fig. 1 Microstructure of material (a)X70 (b)X80 (c)X90 (d)X100.
Item Tempearture/℃ Impact absorbed energy[J] Shear area/% Single value Average value X70 -20 473 479 475 476 100 X80 -20 519 487 493 500 100 X90 -20 468 407 404 426 100 X100 -20 358 331 311 333 100 GB/T1591-2018 -20 Requirement ≥27J / The impact absorbed energy testing results of X70~X100 pipeline steel are shown in Table 3.
Item 1 2 3 4 5 6 7 8 9 X70 1/4 196 198 199 192 197 190 195 195 195 1/2 195 200 194 193 194 200 205 198 202 X80 1/4 268 260 266 232 253 250 252 246 252 1/2 224 225 224 222 219 217 220 226 218 X90 1/4 238 244 238 225 219 223 235 225 226 1/2 268 260 266 232 253 250 252 246 252 X100 1/4 255 255 266 234 237 240 264 266 262 1/2 265 259 273 246 251 247 253 258 248 Comprehensive Analysis Thermo-mechanical controlled rolling (TMCP) is commonly used process in production of high strength pipeline steel.
Table 1 Chemical composition of material.
(a) (b) (d) (c) Fig. 1 Microstructure of material (a)X70 (b)X80 (c)X90 (d)X100.
Item Tempearture/℃ Impact absorbed energy[J] Shear area/% Single value Average value X70 -20 473 479 475 476 100 X80 -20 519 487 493 500 100 X90 -20 468 407 404 426 100 X100 -20 358 331 311 333 100 GB/T1591-2018 -20 Requirement ≥27J / The impact absorbed energy testing results of X70~X100 pipeline steel are shown in Table 3.
Item 1 2 3 4 5 6 7 8 9 X70 1/4 196 198 199 192 197 190 195 195 195 1/2 195 200 194 193 194 200 205 198 202 X80 1/4 268 260 266 232 253 250 252 246 252 1/2 224 225 224 222 219 217 220 226 218 X90 1/4 238 244 238 225 219 223 235 225 226 1/2 268 260 266 232 253 250 252 246 252 X100 1/4 255 255 266 234 237 240 264 266 262 1/2 265 259 273 246 251 247 253 258 248 Comprehensive Analysis Thermo-mechanical controlled rolling (TMCP) is commonly used process in production of high strength pipeline steel.
Online since: January 2005
Authors: László Kuzsella, Péter Arató, Judit Babcsán Kiss, Maria Maros Berkes
Introduction
Si3N4 based ceramics are often applied as high temperature, wear resistant parts of engineering
structures [1].
Fig. 1.
Treatment °C, HV RFPB, MPa E, GPa KC, MPam 1/2 untreated 14,58 479 270 7,89 800 15,22 561 272 5,79 1000 15,29 473 278 7,35 1200 15,04 422 268 6,76 1400 14,00 262 241 6,73 Microstructural investigations The effect of post heat treatment on the microstructure have been analysed by X-ray diffraction and Transmission Electron Microscopy.
Hampshire, S., Elsevier Applied Science Publishers Ltd., 1986, ISBN 1-85166-042-9 [4 ] Maros, B.
No 1-2. pp. 77-90. (2000) [7] Ponton, C.
Fig. 1.
Treatment °C, HV RFPB, MPa E, GPa KC, MPam 1/2 untreated 14,58 479 270 7,89 800 15,22 561 272 5,79 1000 15,29 473 278 7,35 1200 15,04 422 268 6,76 1400 14,00 262 241 6,73 Microstructural investigations The effect of post heat treatment on the microstructure have been analysed by X-ray diffraction and Transmission Electron Microscopy.
Hampshire, S., Elsevier Applied Science Publishers Ltd., 1986, ISBN 1-85166-042-9 [4 ] Maros, B.
No 1-2. pp. 77-90. (2000) [7] Ponton, C.
Online since: September 2015
Authors: Dietmar Eifler, Stefan Heinz
Fig. 1.
Table 1.
The value rODA was used to calculate the stress intensity factor of the ODA by the equation ΔKODA = 0.5 Δσ (Π (Π rODA2)1/2)1/2 according to [13].
References [1] M.
Eifler, Innovative piezoelectrical testing facility for fatigue experiments in the VHCF regime, Proceedings of the Fifth International Conference on Very High Cycle Fatigue (2011), 479-484
Table 1.
The value rODA was used to calculate the stress intensity factor of the ODA by the equation ΔKODA = 0.5 Δσ (Π (Π rODA2)1/2)1/2 according to [13].
References [1] M.
Eifler, Innovative piezoelectrical testing facility for fatigue experiments in the VHCF regime, Proceedings of the Fifth International Conference on Very High Cycle Fatigue (2011), 479-484
Online since: July 2011
Authors: Catherine M.F. Rae, Howard James Stone, H.T. Pang, R.A. Hobbs
Rae1,d
1 Dept. of Materials Science and Metallurgy, University of Cambridge, Pembroke Street, Cambridge CB2 3QZ, United Kingdom.
2 Rolls-Royce plc., P.O.
These alloys were chosen as they possess a systematic variation in the Co, Mo and W contents as shown in Table 1.
Results The TCP phases formed after 1000 hours exposure at 900°C, 1000°C and 1100°C are shown in Fig. 1.
The TCP precipitates in LDSX1 and 4 (Figs. 1-2) are found predominantly at the dendrite cores in all conditions.
A Vol. 479 (2008), p. 148 ].
These alloys were chosen as they possess a systematic variation in the Co, Mo and W contents as shown in Table 1.
Results The TCP phases formed after 1000 hours exposure at 900°C, 1000°C and 1100°C are shown in Fig. 1.
The TCP precipitates in LDSX1 and 4 (Figs. 1-2) are found predominantly at the dendrite cores in all conditions.
A Vol. 479 (2008), p. 148 ].