Line Pipe for Sour Service |
The line pipes can be used for a wide range of petrol and gas transportation under sour service environment.
Standards:
- GB/T9711.3
- API5l/ISO3183-2007
Application:
- For petrol and gas transportation under sour service environment.
Sizes range
- 1/4 inch Nominal to 24 inchO.D.
- Wall Thickness-Schedule 10 through XXH
Line Pipe Steels Used in Sour Service
Line pipe steels used in sour service are prone to hydrogen-induced cracking (HIC) depending on metallurgical and environmental factors.
The metallurgical factors consist of alloying elements, microstructure, strength, segregation, and shape of non-metallic inclusions. Some environmental factors which influence HIC, also known as stepwise cracking (SWC), are the partial pressures of hydrogen sulfide (H2S) and carbon dioxide, temperature, pH of the medium, and aggressive ions, such as chloride. Many failures of sour gas line pipes have occurred around the world as a result of HIC.
The metallurgical factors consist of alloying elements, microstructure, strength, segregation, and shape of non-metallic inclusions. Some environmental factors which influence HIC, also known as stepwise cracking (SWC), are the partial pressures of hydrogen sulfide (H2S) and carbon dioxide, temperature, pH of the medium, and aggressive ions, such as chloride. Many failures of sour gas line pipes have occurred around the world as a result of HIC.
Considerable effort has been expended by steel line pipe producers, users, and research organizations to understand the HIC mechanism, to develop a laboratory test method to identify and quantify material susceptibility to HIC, and to produce steels with greater HIC resistance. NACE International has developed a standard test, TM-02-84, for line pipe steels.
The method describes procedures for evaluating the resistance of pipeline steels to SWC induced by H absorption from aqueous sulfide corrosion. The test is applicable to line pipe with wall thicknesses of 5 mm to 30 mm. The procedure consists of exposing unstressed coupons to synthetic seawater saturated with H2S at ambient temperature and pressure at a pH in the range 4.8 to 5.4 for 96 h. The samples are sectioned, polished metallographically, and etched, if necessary, so that cracks can be distinguished from small inclusions, laminations, scratches, or discontinuities. Crack sensitivity ratio (CSR), crack length ratio (CLR), and crack thickness ratio (CTR) are calculated for each section. The average is determined for each coupon. In recent work by Canada’s Centre for Mineral and Energy
Technology in collaboration with the Canadian Standards Association (CSA) Sour Service Task Force, two parameters were determined experimentally for each of 19 line pipe steels:
(1) threshold H concentration (CthH) or the concentration of diffusible H in the steel above which cracking occurs and
(2) threshold pH (pHth) or the pH below which cracking occurs.
(1) threshold H concentration (CthH) or the concentration of diffusible H in the steel above which cracking occurs and
(2) threshold pH (pHth) or the pH below which cracking occurs.
Chemical composition for pipe with t ≤25,0 mm (0.984 in)
Mass fraction, based upon heat and product analyses
Steel grade | Chemical composition for pipe with t ≤25,0 mm (0.984 in) | Carbon equivalent | |||||||||
%, Max | % maximum | ||||||||||
C b | Si | Mn b | P | S | V | Nb | Ti | Otherc, d | CEllw | CEpcm | |
L245NS or BNS | 0,14 | 0,40 | 1,35 | 0,020 | 0,003e | f | f | 0,04 | g | 0,36 | 0,19 h |
L290NS or X42NS | o,14 | 0,40 | 1,35 | 0,020 | 0,003e | 0,05 | 0,05 | 0,04 | - | 0,36 | 0,19 h |
L320NS or X46NS | 0,14 | 0,40 | 1,40 | 0,020 | 0,003e | 0,07 | 0,05 | 0,04 | g | 0,38 | 0,20 h |
L360NS or X52NS | 0,16 | 0,45 | 1,65 | 0,020 | 0,003e | 0,10 | 0,05 | 0,04 | g | 0,43 | 0,22 h |
L245QS or BQS | 0,14 | 0,40 | 1,35 | 0,020 | 0,003e | 0,04 | 0,04 | 0,04 | - | 0,34 | 0,19 h |
L 290QS or X42QS | 0,14 | 0,40 | 1,35 | 0,020 | 0,003e | 0,04 | 0,04 | 0,04 | - | 0,34 | 0,19 h |
L320QS or X46QS | 0,15 | 0,45 | 1,40 | 0,020 | 0,003e | 0,05 | 0,05 | 0,04 | - | 0,36 | 0,20 h |
L360QS or X52QS | 0,16 | 0,45 | 1,65 | 0,020 | 0,003e | 0,07 | 0,05 | 0,04 | g | 0,39 | 0,20 h |
L390QS or X56QS | 0,16 | 0,45 | 1,65 | 0,020 | 0,003e | 0,07 | 0,05 | 0,04 | g | 0,40 | 0,21 h |
L415QS or X60QS | 0,16 | 0,45 | 1,65 | 0,020 | 0,003e | 0,08 | 0,05 | 0,04 | g,i,k | 0,41 | 0,22 h |
L450QS or X65QS | 0,16 | 0,45 | 1,65 | 0,020 | 0,003e | 0,09 | 0,05 | 0,06 | g,i,k | 0,42 | 0,22 h |
L485QS or X70QS | 0,16 | 0,45 | 1,65 | 0,020 | 0,003e | 0,09 | 0,05 | 0,06 | g,i,k | 0,42 | 0,22 h |
Note:
a ) Based upon product analysis (see 9.2.4 and 9.2.5) The CEllw limits apply if the carbon mass fraction is greater than 0,12 % and the CEpcm limits apply if the carbon mass fraction is less than or equal to 0,12 %.
b ) For each reduction of 0,01 % below the specified maximum for carbon, an increase of 0,05 % above the specified maximum for manganese is permissible, up to a maximum increase of 0,20 %.
c ) AI total ≤ 0,060 %; N ≤ 0,012 %; AI/N ≥ 2:1 (not applicable to titanium-killed or titanium-treated steel); Cu ≤ 0,35 % (if agreed ,Cu ≤ 0,10 %); Ni ≤ 0,30 %; Cr ≤ 0,30 %; Mo ≤ 0,15 %; B ≤ 0,0005 %.
d ) For welded pipe where calcium is intentionally added, unless otherwise agreed, Ca/s ≥ 1,5 if S < 0,0015 % For SMLS and welded pipes, the calcium concentration shall be ≤ 0,006 %.
e ) The maximum limit for sulfur concentration may be increased to ≤ 0,008 % for SMLS pipe and, if agreed, to ≤ 0,006 % for welded pipe. For such higher-sulfur levels in welded pipe, lower Ca/s ratios may be agreed.
f ) Unless otherwise agreed, the sum of the niobium and vanadium concentrations shall be ≤ 0,06 %.
g ) The sum of the niobium, vanadium and titanium concentrations shall be ≤ 0,15 %.
h ) For SMLS pipe, the listed value may be increased by 0,03.
i ) If agreed, the molybdenum concentration shall be ≤ 0,35 %.
j ) If agreed, the the chromium concentration shall be ≤ 0,45 %.
k ) If agreed, Cr concentration shall be ≤ 0,45 % and Ni concentration shall be ≤ 0,50 %.
b ) For each reduction of 0,01 % below the specified maximum for carbon, an increase of 0,05 % above the specified maximum for manganese is permissible, up to a maximum increase of 0,20 %.
c ) AI total ≤ 0,060 %; N ≤ 0,012 %; AI/N ≥ 2:1 (not applicable to titanium-killed or titanium-treated steel); Cu ≤ 0,35 % (if agreed ,Cu ≤ 0,10 %); Ni ≤ 0,30 %; Cr ≤ 0,30 %; Mo ≤ 0,15 %; B ≤ 0,0005 %.
d ) For welded pipe where calcium is intentionally added, unless otherwise agreed, Ca/s ≥ 1,5 if S < 0,0015 % For SMLS and welded pipes, the calcium concentration shall be ≤ 0,006 %.
e ) The maximum limit for sulfur concentration may be increased to ≤ 0,008 % for SMLS pipe and, if agreed, to ≤ 0,006 % for welded pipe. For such higher-sulfur levels in welded pipe, lower Ca/s ratios may be agreed.
f ) Unless otherwise agreed, the sum of the niobium and vanadium concentrations shall be ≤ 0,06 %.
g ) The sum of the niobium, vanadium and titanium concentrations shall be ≤ 0,15 %.
h ) For SMLS pipe, the listed value may be increased by 0,03.
i ) If agreed, the molybdenum concentration shall be ≤ 0,35 %.
j ) If agreed, the the chromium concentration shall be ≤ 0,45 %.
k ) If agreed, Cr concentration shall be ≤ 0,45 % and Ni concentration shall be ≤ 0,50 %.
Requirements for the results of tensile tests
Pipe steel grade | Yield strength a Rto,5 Mpa (psi) | Tensile strength a Rm Mpa (psi) | Ratio b Rto,5/Rm | Elongation A % | ||
minimum | maximum | minimum | maximum | maximum | minimum | |
L245NS or BNS L245QS or BQS | 245 (35 500) | 450 (65 300) | 415 (60 200) | 760 (110 200) | 0,93 | API SPEL 5L |
L290NS or X42NS L290QS or X42QS | 290 (42 100) | 495 (71 800) | 415 (60 200) | 760 (110 200) | 0,93 | API SPEL 5L |
L320NS or X46NS L320QS or X46QS | 320 (46 400) | 525 (76 100) | 435 (63 100) | 760 (110 200) | 0,93 | API SPEL 5L |
L360NS or X52NS L360QS or X52QS | 360 (52 200) | 530 (76 900) | 460 (66 700) | 760 (110 200) | 0,93 | API SPEL 5L |
L390QS or X56QS | 390 (56 600) | 545 (79 000) | 490 (71 100) | 760 (110 200) | 0,93 | API SPEL 5L |
L415QS or X60QS | 415 (60 200) | 565 (81 900) | 520 (75 400) | 760 (110 200) | 0,93 | API SPEL 5L |
L450QS or X65QS | 450 (65 300) | 600 (87 000) | 535 (77 600) | 760 (110 200) | 0,93 | API SPEL 5L |
L485QS or X70QS | 485 (70 300) | 635 (92 100) | 570 (82 700) | 760 (110 200) | 0,93 | API SPEL 5L |
Requirements for the results of tensile tests
For intermediate grades, the difference between the specified maximum yield strength and the specified minimum yield strength shall be as given in the table for the next higher grade, and the difference between the specified minimum tensile strength and the specified minimum yield strength shall be as given in the table for the next higher grade, For intermediate grades, the tensile strength shall be ≤ 760 MPa (110 200 psi).
This limit applies for pipe with D <323, 9 mm (12.750 in).
For intermediate grades, the specified minimum tensile strength for the weld seam shall be the same value as was determined for the pipe body using footnote a).
For pipe with D
This limit applies for pipe with D <323, 9 mm (12.750 in).
For intermediate grades, the specified minimum tensile strength for the weld seam shall be the same value as was determined for the pipe body using footnote a).
For pipe with D