ASTM GB JIS A36 A53 A192 Q235 Q235B 1045 4130 Sch40 10mm 60mm Carbon Steel Construction Pipe for Oil and Gas Pipeline Construction
astm GB JIS A36 A53 A192 Q235 Q235B 1045 4130 Sch40 10mm 60mm carbon steel Construction Pipe for Oil and gas pipeline Construction ASTM GB JIS A36 A53 A192 Q235 Q235B 1045 4130 Sch40 10mm 60mm Carbon Steel Construction Pipe for Oil and Gas Pipeline Construction Carbon steel construction pipes play a crucial role in...
astm GB JIS A36 A53 A192 Q235 Q235B 1045 4130 Sch40 10mm 60mm carbon steel Construction Pipe for Oil and gas pipeline Construction
ASTM GB JIS A36 A53 A192 Q235 Q235B 1045 4130 Sch40 10mm 60mm Carbon Steel Construction Pipe for Oil and Gas Pipeline Construction Carbon steel construction pipes play a crucial role in the oil and gas industry. these pipes are used for the transportation of oil and gas from the extraction site to refineries and distribution centers. The choice of the right construction pipe is essential to ensure the safe and efficient operation of the pipeline system. In this article, we will discuss the ASTM GB JIS A36 A53 A192 Q235 Q235B 1045 4130 Sch40 10mm 60mm carbon steel construction pipe and its significance in oil and gas pipeline construction. The ASTM GB JIS A36 A53 A192 Q235 Q235B 1045 4130 Sch40 10mm 60mm carbon steel construction pipe is a widely used pipe material in the oil and gas industry. It is made from carbon steel, which provides excellent strength and durability. The pipe is available in various sizes, ranging from 10mm to 60mm in diameter, making it suitable for different pipeline construction requirements. One of the key advantages of the ASTM GB JIS A36 A53 A192 Q235 Q235B 1045 4130 Sch40 10mm 60mm carbon steel construction pipe is its compatibility with various international standards. It meets the requirements of ASTM, GB, JIS, and other industry standards, ensuring its quality and reliability. This makes it a preferred choice for oil and gas pipeline construction projects worldwide. The Sch40 designation of the construction pipe refers to its wall thickness. Sch40 pipes have a standard wall thickness, which provides the necessary strength to withstand the high pressure and stress encountered during oil and gas transportation. The Sch40 thickness ensures the pipe’s integrity and prevents any Leakage or failure in the pipeline system.Labels a | Calculated Mass c | ||||||||||
Nominal Linear Mass T& C b,c | Wall Thick- ness | em, Mass Gain or Loss Due to End Finishing d | |||||||||
Outside Diameter | Inside Diameter | Drift Diameter | Plain- end | kg | |||||||
round thread | Buttress Thread | ||||||||||
wpe | |||||||||||
D | kg/m | t | D | mm | kg/m | short | long | RC | SCC | ||
mm | mm | mm | |||||||||
1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 |
13 3/8 | 48 | 339.72 | 71.43 | 8.38 | 322.96 | 318.99 | 68.48 | 15.04 | — | — 17.91 | — |
13 3/8 | 54.5 | 339.72 | 81.1 | 9.65 | 320.42 | 316.45 | 78.55 | 13.88 | — | 16.44 | — |
13 3/8 | 61 | 339.72 | 90.78 | 10.92 | 317.88 | 313.91 | 88.55 | 12.74 | — | 14.97 | — |
13 3/8 | 68 | 339.72 | 101.19 | 12.19 | 315.34 | 311.37 | 98.46 | 11.61 | — | 14.97 | — |
13 3/8 | 68 | 339.72 | 101.19 | 12.19 | 315.34 | 311.37 | 98.46 | 11.67 f | — | 14.33 | — |
13 3/8 | 72 | 339.72 | 107.15 | 13.06 | 313.6 | 311.15 e | 105.21 | 10.98 | — | 13.98 | — |
13 3/8 | 72 | 339.72 | 107.15 | 13.06 | 313.6 | 311.15 e 309.63 309.63 | 105.21 | 10.91 f | — | 14.33 | — |
13 3/8 | 72 | 339.72 | 107.15 | 13.06 | 313.6 | 105.21 | 10.98 | — | 13.98 | — | |
13 3/8 | 72 | 339.72 | 107.15 | 13.06 | 313.6 | 105.21 | 10.91 e | — | — | ||
16 | 65 | 406.4 | 96.73 | 9.53 | 387.4 | 382.57 | 96.73 | 18.59 | — | — 20.13 | — |
16 | 75 | 406.4 | 111.61 | 11.13 | 384.1 | 379.37 | 108.49 | 16.66 | — | 18.11 | — |
16 | 84 | 406.4 | 125.01 | 12.57 | 381.3 | 376.48 | 122.09 | 14.92 | — | — | — |
16 | 109 | 406.4 | 162.21 | 16.66 | 373.1 | 368.3 | 160.13 | — | — | — | |
18 5/8 | 87.5 | 473.08 | 130.21 | 11.05 | 450.98 | 446.22 | 125.91 | 33.6 | — | 39.25 | — |
20 | 94 | 508 | 139.89 | 11.13 | 485.7 | 480.97 | 136.38 | 20.5 | 27.11 | 24.78 | — |
20 | 94 | 508 | 139.89 | 11.13 | 485.7 | 480.97 | 136.38 | 20.61 | 27.26 g 24.27 17.84 | 24.78 | — |
20 | 106.5 | 508 | 158.49 | 12.7 | 482.6 | 477.82 | 155.13 | 18.22 | 22 | — | |
20 | 133 | 508 | 197.93 | 16.13 | 475.7 | 470.97 | 195.66 | 13.03 | 16.02 | — | |
NOTE See also Figures D.1, D.2, and D.3. | |||||||||||
a Labels are for information and assistance in ordering. | |||||||||||
b Nominal linear masses, threaded and coupled (Column 4) are shown for information only. | |||||||||||
c The densities of martensitic chromium steels (L80 types 9Cr and 13Cr) are less than those of carbon steels; The masses shown are therefore not accurate for martensitic chromium steels; A mass correction factor of 0.989 shall be used. | |||||||||||
d Mass gain or loss due to end finishing; See 8.5. | |||||||||||
e Drift diameter for most common bit size; This drift diameter shall be specified in the purchase agreement and marked on the pipe; See 8.10 for drift requirements. | |||||||||||
f based on 758 mPa minimum yield strength or greater. | |||||||||||
g Based on 379 mPa minimum yield strength. |