Savoy Piping Inc. we carry a full inventory of API 5L X56 SSC Tested Pipe Steel Products in a variety of sizes to meet the structural piping requirements for applications the water, petroleum, oil & gas and other industries. API 5L X56 SSC Tested Pipe Carbon Steel Pipe can be Structural in Nature or used in Fluid, Gas, Oil Transmission.
We Supply API 5L SSC Tested Line Pipe in API 5L X56 SSC Tested Pipe, API 5L X56 SSC Tested Pipe, API 5L X56 SSC Tested Pipe, API 5L X56 SSC Tested Pipe, API 5L X56 SSC Tested Pipe, API 5L X60 SSC Tested Pipe, API 5L X65 SSC Tested Pipe.
Savoy Piping Inc. specializes in API 5L X52 SSC Tested Pipe with years of Experience in Manufacturing API 5L X56 SSC Tested Carbon Steel Pipe we offer high quality, lower cost but the best service. As a result to that our API 5L X56 SSC Tested Pipes export account today is in various countries like Iran, Iraq, Kuwait, Saudi Arabia, Oman, UAE, Singapore, Malaysia, Indonesia, South korea, Chile, Peru, Venezuela, Australia, Nigeria, Angola, Senegal, Mozambique, Algeria, Libya, Azerbaijan, Netherlands, Brazil, Norway, United Kingdom, Mexico, Canada etc.
API 5L X56 SSC Tested Pipe is a type of steel pipe that conforms to the specifications outlined in the American Petroleum Institute (API) 5L standard. The API 5L standard is widely used in the oil and gas industry to regulate the manufacturing and transportation of steel pipes for conveying fluids such as oil, gas, and water. The "X56" designation in API 5L X56 refers to the minimum yield strength of the steel, which is 56,000 psi (pounds per square inch). The termSSC Test in API 5L X56 SSC Tested Pipe stands for Sulfide Stress Cracking Tested. is a form of corrosion that can occur in certain environments, particularly in the presence of hydrogen sulfide (H2S) gas. SSC testing is conducted to ensure that the steel used in the pipe is resistant to this type of cracking, which is crucial for pipelines operating in sour gas (H2S-containing) environments. API 5L X56 SSC Tested Pipe undergoes rigorous testing procedures to confirm its suitability for use in challenging conditions. These tests often include mechanical testing, chemical analysis, and SSC testing. The goal is to ensure the pipe's integrity, strength, and resistance to environmental factors, especially in environments prone to sulfide stress cracking.
SSC testing of X80, X90, and X90-C steel. It can be seen that the time to failure increases as the load decreases for the X90 and X90-C steels. This clearly suggests that the higher the load, the more easily SSC occurs. However, in the case of X80, it did not break even after 720 hours under YS load of 90%, demonstrating excellent SSC resistance. Furthermore, X90 showed lower SSC susceptibility than his X90-C. The cross section of the fractured sample after the SSC test was observed using SEM. Figure 6 shows the typical SSC crack behavior of X90-C at 80% yield strength. SSC crack spread
perpendicular to the applied voltage. The fractogram shows two main parts. quasi-cleavage fracture induced by Sulfide Stress Corrosion and ductile fracture induced by applied stress. The main SSC crack propagated perpendicular to the applied stress. Large M/A islands are one of the main locations where surface cracks can form. Stress concentration at the M/A island-matrix interface leads to crack formation and subsequent propagation. More explanation later
detail.
Both HIC and SSC of pipeline steel in H2S-containing environments can be explained by Hydrogen Embrittlement (HE) theory. HE processes typically involve hydrogen generation in the environment, hydrogen absorption at the steel surface, hydrogen diffusion into the steel, and hydrogen release into potential locations (inclusions, grain boundaries, large M/A islands, precipitates). It consists of several steps: the accumulation of hydrogen atoms. carbide, etc.)
The internal pressure of Hydrogen Gas initiates crack formation and the crack propagates. Generally, when corrosion occurs on the surface of steel, hydrogen atoms are generated. These atoms combine to form hydrogen gas. Some of the hydrogen gas escapes into the environment, while another part penetrates the steel. Matrix However, as a toxic reagent, hydrogen sulfide retards the recombination reaction of hydrogen atoms to form molecular hydrogen, and this toxic effect promotes the diffusion of atomic hydrogen into the steel. The results reported by Zapffe et al. The proposed internal pressure theory of HE is based on hydrogen accumulation. It can be used to explain the HIB crack in Figure 4. When hydrogen atoms diffuse into the steel, they become trapped in potential locations.As previously mentioned, all test steels were carefully inspected and melted clean, so no obvious inclusions were found. Therefore, the influence of inclusions can be ignored.
NACE TM0284 specifies either Solution A or Solution B. Solution A is acidified brine. Solution B is simulated seawater prepared in accordance with ASTM D1141.52. In either case, H2S is bubbled through the solution constantly throughout the test period. NACE TM0284 specifies test duration of 96 hours.
A detailed written report upon completion of each test. Each report includes a description of the test sample that was received, the test procedure that was used, and the pH values of the test solution before exposure and after the exposure. The test bars are cut into sections and examined under a microscope for hydrogen-induced cracks. The dimensions of any such cracks are recorded and used to compute the values in percentage for Crack Length Ratio (CLR), Crack Thickness Ratio (CTR) and Crack Sensitivity Ratio (CSR).
API 5L X56 SSC Tested Pipe Specification | API 5L / ISO 3183 Hot Rolled. |
API 5L X56 SSC Tested Pipe Grades | API 5L X56 PSL1, PSL 2 / API 5L X56 PSL1, PSL 2 / API 5L X56 PSL1, PSL 2 / API 5L X56 PSL1, PSL 2 / API 5L X56 PSL1, PSL 2 / API 5L X60 PSL1, PSL 2 / API 5L X65 PSL1, PSL 2 / X70 PSL1, PSL 2 / API 5L X70 PSL1 / PSL2 / API 5CT /API 5L X80 PSL1, PSL 2 / ISO 3183 L245 PSL1, PSL 2, ISO 3183 L290 PSL1, PSL 2, ISO 3183 L320 PSL1, PSL2, ISO 3183 L360 PSL1, PSL 2, ISO 3183 L390 PSL1, PSL 2, ISO 3183 L415 PSL1, PSL 2, ISO 3183 L450 PSL1, PSL 2, ISO 3183 L485 PSL1, PSL 2 |
API 5L X56 SSC Tested Pipe Type | Seamless |
API 5L X56 SSC Tested Pipe Outer Diameter Size | 3/8" NB to 30" NB (Nominal Bore Size) |
API 5L X56 SSC Tested Pipe Wall Thicknesss | Schedule 20 to Schedule XXS (Heavier On Request) Up to 250 mm Thicknesss |
API 5L X56 SSC Tested Pipe Length | 5 to 7 Meters, 09 to 13 Meters, Single Random Length, Double Random Length And Customize Size. |
API 5L X56 SSC Tested Pipe Ends | Plain Ends / Beveled Ends / Coupling |
API 5L X56 SSC Tested Pipe Delivery Conditions | As Rolled, Normalizing Rolled, Thermomechanical Rolled / Formed, Normalizing Formed, Normalized and Tempered / Quenched and Tempered - BR / N / Q /T |
API 5L X56 SSC Tested Pipe Coating | Epoxy Coating / Colour Paint Coating / 3LPE Coating. |
API 5L X56 SSC Tested Pipe Other Testing | NACE MR0175, NACE TM0177, NACE TM0284, SSC TEST, SSC TEST, SWC, H2 SERVICE, IBR, Etc. |
API 5L X56 SSC Tested Pipe Dimension | All Pipes Tube Is Manufactured and Inspected / Tested to the Relevant standards including ASTM, ASME, API. |
API 5L X56 SSC Tested Pipe Value Added Services | Draw / Expansion / Machining / Sand Blasting / Shot Blasting / Galavanizing / Heat Treatment |
API 5L X56 SSC Tested Pipe Packaging | Loose / Bundle / Wooden Pallet / Wooden box-a / Plastic Cloth Wraps / Plastic End Caps / Beveled Protector |
API 5L X56 SSC Tested Pipe Shipment & Transportation | By Road - Truck / Train, By Sea - Break-bulk Conventional Vessel / FCL (Full Container Load) / LCL (Less Container Load) / 20 Feet Container / 40 Feet |
API 5L X56 SSC Tested Pipe Material Test Certificate | Manufacturer Test Certificate As Per EN10204 3.1, 3.2 / Laboratory Test Certificate From NABL Approved Lab./ Under Third Party Inspection Agency Like SGS, TUV, DNV, LLOYDS, ABS ETC |
H.1 IntroductionThis annex specifies additional provisions that apply for PSL 2 pipe that is ordered for sour service [see 7.2 c) 51 ] . |
H.2 Additional information to be supplied by the purchaserin addition to items a) to g) as specified by 7.1, the purchase order shall indicate which of the following provisions apply for the specific order item:a) steel casting method for strip or plate used for the manufacture of welded pipe (see H.3.3.2.1); b) ultrasonic inspection of strip or plate for laminar imperfections (see H.3.3.2.4); c) supply of helical-seam pipe containing strip/plate end welds (see H.3.3.2.5); d) chemical composition for intermediate grades (see H.4.1.1); e) chemical composition for pipe with t > 25,0 mm (0.984 in) (see H.4.1.2); f) chemical composition limits (see Table H.1, footnotes c), d,) e), f), i), j)and k); g) frequency of hardness testing of the longitudinal seam weld of HFW or SAW pipe (see Table H.3); h) SSC test for manufacturing procedure qualification (see Table H.3); i) alternative HIC/SWC test methods and associated acceptance criteria (see H.7.3.1.3); j) photomicrographs of reportable HIC cracks (see H.7.3.1.4); k) alternative SSC test methods and associated acceptance criteria for manufacturing procedure qualification (see H.7.3.2.2); l) for pipe with t ≥ 5,0 mm (0.197 in), ultrasonic inspection for laminar imperfections with in extended length of 100 mm (4.0 in) at the pipe ends (see K.2.1.3); m) magnetic particle inspection for laminar imperfections at each pipe end face/bevel (see K.2.1.4); |
Table H.1 --- Chemical Composition for pipe with t ≤25,0 mm (0.984 in)
Steel grade | Mass fraction, based upon heat and product analyses % maximum |
Carbon equivalent a % maximum |
|||||||||
C b | Si | Mn b | P | S | V | Nb | Ti | Other c, d | CE llw | CE pcm | |
SMLS and welded Pipes | |||||||||||
L245NS or BNS | 0,14 | 0,40 | 1,35 | 0,020 | 0,003 e | f | f | 0,04 | g | 0,36 | 0,19 h |
L290NS or X56NS | o,14 | 0,40 | 1,35 | 0,020 | 0,003 e | 0,05 | 0,05 | 0,04 | - | 0,36 | 0,19 h |
L320NS or X56NS | 0,14 | 0,40 | 1,40 | 0,020 | 0,003 e | 0,07 | 0,05 | 0,04 | g | 0,38 | 0,20 h |
L360NS or X56NS | 0,16 | 0,45 | 1,65 | 0,020 | 0,003 e | 0,10 | 0,05 | 0,04 | g | 0,43 | 0,22 h |
L245QS or BQS | 0,14 | 0,40 | 1,35 | 0,020 | 0,003 e | 0,04 | 0,04 | 0,04 | - | 0,34 | 0,19 h |
L 290QS or X56QS | 0,14 | 0,40 | 1,35 | 0,020 | 0,003 e | 0,04 | 0,04 | 0,04 | - | 0,34 | 0,19 h |
L320QS or X56QS | 0,15 | 0,45 | 1,40 | 0,020 | 0,003 e | 0,05 | 0,05 | 0,04 | - | 0,36 | 0,20 h |
L360QS or X56QS | 0,16 | 0,45 | 1,65 | 0,020 | 0,003 e | 0,07 | 0,05 | 0,04 | g | 0,39 | 0,20 h |
L390QS or X56QS | 0,16 | 0,45 | 1,65 | 0,020 | 0,003 e | 0,07 | 0,05 | 0,04 | g | 0,40 | 0,21 h |
L415QS or X60QS | 0,16 | 0,45 | 1,65 | 0,020 | 0,003 e | 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 | 0,003 e | 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 | 0,003 e | 0,09 | 0,05 | 0,06 | g,i,k | 0,42 | 0,22 h |
welded pipe | |||||||||||
L245MS or BMS | 0,10 | 0,40 | 1,25 | 0,020 | 0,002 e | 0,04 | 0,04 | 0,04 | - | - | 0,19 |
L290MS or X56MS | 0,10 | 0,40 | 1,25 | 0,020 | 0,002 e | 0,04 | 0,04 | 0,04 | - | - | 0,19 |
L320MS or X56 MS | 0,10 | 0,45 | 1,35 | 0,020 | 0,002 e | 0,05 | 0,05 | 0,04 | - | - | 0,20 |
L360MS or X56 MS | 0,10 | 0,45 | 1,45 | 0,020 | 0,002 e | 0,05 | 0,06 | 0,04 | - | - | 0,20 |
L390MS or X56 MS | 0,10 | 0,45 | 1,45 | 0,020 | 0,002 e | 0,06 | 0,08 | 0,04 | g | - | 0,21 |
L415MS or X60 MS | 0,10 | 0,45 | 1,45 | 0,020 | 0,002 e | 0,08 | 0,08 | 0,06 | g,i | - | 0,21 |
L450MS or X65MS | 0,10 | 0,45 | 1,60 | 0,020 | 0,002 e | 0,10 | 0,08 | 0,06 | g,i,j | - | 0,22 |
L485MS or X70 MS | 0,10 | 0,45 | 1,60 | 0,020 | 0,002 e | 0,10 | 0,08 | 0,06 | g,i,j | - | 0,22 |
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 %. |
Pipe steel grade | Pipe body of SMLS and welded Pipes | Weld seam of HFW and SAW Pipes | |||||
Yield strength a Rto,5 Mpa (psi) |
Tensile strength a Rm Mpa (psi) |
Ratio b Rto,5/Rm |
Elongation on 50 mm or 2 in Af % |
Tensile strength c Rm Mpa (psi) |
|||
minimum | maximum | minimum | maximum | maximum | minimum | minimum | |
L245NS or BNS L245QS or BQS L245MS or BMS |
245 (35 500) |
450 d (65 300) d |
415 (60 200) |
760 (110 200) |
0,93 | e | 415 (60 200) |
L290NS or X56NS L290QS or X56QS L290MS or X56MS |
290 (42 100) |
495 (71 800) |
415 (60 200) |
760 (110 200) |
0,93 | e | 415 (60 200) |
L320NS or X56NS L320QS or X56QS L320MS or X56MS |
320 (56 400) |
565 (76 100) |
435 (63 100) |
760 (110 200) |
0,93 | e | 435 (63 100) |
L360NS or X56NS L360QS or X56QS L360MS or X56MS |
360 (56 200) |
530 (76 900) |
560 (66 700) |
760 (110 200) |
0,93 | e | 560 (66 700) |
L390QS or X56QS L390MS or X56MS |
390 (56 600) |
545 (79 000) |
490 (71 100) |
760 (110 200) |
0,93 | e | 490 (71 100) |
L415QS or X60QS L415MS or X60MS |
415 (60 200) |
565 (81 900) |
560 (75 400) |
760 (110 200) |
0,93 | e | 560 (75 400) |
L450QS or X65QS L450MS or X65MS |
450 (65 300) |
600 (87 000) |
535 (77 600) |
760 (110 200) |
0,93 | e | 535 (77 600) |
L485MS or X70MS | 485 (70 300) |
635 (92 100) |
570 (82 700) |
760 (110 200) |
0,93 | e | 570 (82 700) |
Table H.2 ----Requirements for the results of Tensile Tests
Pipe steel grade | Pipe body of SMLS and welded Pipes | Weld seam of HFW and SAW Pipes | |||||
Yield strength a Rto,5 Mpa (psi) |
Tensile strength a Rm Mpa (psi) |
Ratio b Rto,5/Rm |
Elongation on 50 mm or 2 in Af % |
Tensile strength c Rm Mpa (psi) |
|||
minimum | maximum | minimum | maximum | maximum | minimum | minimum | |
L245NS or BNS L245QS or BQS L245MS or BMS |
245 (35 500) |
450 d (65 300) d |
415 (60 200) |
760 (110 200) |
0,93 | e | 415 (60 200) |
L290NS or X56NS L290QS or X56QS L290MS or X56MS |
290 (42 100) |
495 (71 800) |
415 (60 200) |
760 (110 200) |
0,93 | e | 415 (60 200) |
L320NS or X56NS L320QS or X56QS L320MS or X56MS |
320 (56 400) |
565 (76 100) |
435 (63 100) |
760 (110 200) |
0,93 | e | 435 (63 100) |
L360NS or X56NS L360QS or X56QS L360MS or X56MS |
360 (56 200) |
530 (76 900) |
560 (66 700) |
760 (110 200) |
0,93 | e | 560 (66 700) |
L390QS or X56QS L390MS or X56MS |
390 (56 600) |
545 (79 000) |
490 (71 100) |
760 (110 200) |
0,93 | e | 490 (71 100) |
L415QS or X60QS L415MS or X60MS |
415 (60 200) |
565 (81 900) |
560 (75 400) |
760 (110 200) |
0,93 | e | 560 (75 400) |
L450QS or X65QS L450MS or X65MS |
450 (65 300) |
600 (87 000) |
535 (77 600) |
760 (110 200) |
0,93 | e | 535 (77 600) |
L485MS or X70MS | 485 (70 300) |
635 (92 100) |
570 (82 700) |
760 (110 200) |
0,93 | e | 570 (82 700) |
a 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). b This limit applies for pipe with D >323, 9 mm (12.750 in). U is the specified minimum tensile strength, expressed in megapascals (pounds per square inch). |
H.4.3 HIC/SWC testThe test for evaluation of resistance-to hydrogen- induced cracking shall meet the following acceptance criteria, with each ratio being the maximum permissible average for three sections per test specimen when tested in solution (Environment) A (see ISO 15156-2:2003, Table B.3):a) crack sensitivity ratio (CSR) ≤ 2 %; b) crack length ratio (CLR) ≤ 15 %; c) crack thickness ratio (CTR) ≤ 5 %; If HIC/SWC tests are conducted in alternative . media (see H.7.3.1.3) to simulate specific service conditions, alternative acceptance criteria may be agreed. |
H.4.4 Hardness testFor test pieces subjected to a hardness test (see H.7.3), the hardness in the pipe body, the weld and HAZ shall be ≤ 250 HV10 or 22 HRC (70,6 HR 15N). The maximum acceptabie hareness of an unexposed weld cap and external surface HAZ and base metal may be 275 HV10 or 26 HRC (73,0 HR 15N) where the equipment user agrees to the alternative weld cap hardness limit, the parent pipe wall thickness is greater than 9 mm, the weld cap is not exposed directly to the sour environment and the escape of hydrogen is not impeded, e.g by cathodic protection. |
The information here is summarized from ASTM Standards and API Specification 5L. Please see the specific standards for more information.
Grade Range | A25 THROUGH X70 | GR B THROUGH X80 | TABLE 1 |
SIZE Range | 0.405 THROUGH 80 | 4-2/1 THROUGH 80 | TABLE 1 |
TYPE OF Pipe ENDS | PLAIN-END, THREADED-END, BEVELLED-END, SPECIAL COUPLING Pipe | PLAIN-END | TABLE 1 |
SEAM WELDING | ALL METHODS CONTINOUS WELDING LIMITED TO Grade A25 | ALL METHODS EXCEPT CONTINOUS AND LASER WELDING | TABLE 1 |
ELECTRIC WELDS: WELDER FREQUENCY | NO MINIMUM | 100 KHZ MINIMUM | 5.1.3.3.2 |
HEAT TREATMENTS OF ELECTRIC WELDS | REQUIRED for GRADES > X56 | REQUIRED for ALL GRADES (GR B THROUGH X80) | 5.1.3.3.1; J.3.3.2:6.2.7 |
CHEMISTRY: MAX C for Seamless Pipe | 0.28% for GRADES > GR B | 0.24% | TABLES 2A, 2B |
CHEMISTRY: MAX C for Welded Pipe | 0.26% for GRADES > GR B | 0.22% | TABLES 2A, 2B |
CHEMISTRY: MAX P | 0.03% | 0.03% | TABLES 2A, 2B |
CHEMISTRY: MAX S | ONLY WHEN PURCHASES SPECIFIES SR18 | 0.02% | TABLES 2A, 2B |
Carbon EQUIVALENT | NONE | MAXIMUM REQUIRED for EACH GRADE | 4.2:4.3:6.1.3: SR15.1 |
YIELD STRENGTH, MAXIMUM | NONE | MAXIMUM for EACH GRADE | TABLES 3A, 3B |
UTS, MAXIMUM | NONE REQUIRED | MAXIMUM for EACH GRADE | TABLES 3A, 3B |
FRACTURE TOUGHNESS | ONLY WHEN PURCHASER SPECIFIES SR4 | REQUIRED for ALL GRADES | 6.2.6; 9.3.5: 9.8.4; 9.10.7; |
NON-DESTRUCTIVE INSPECTION OF Seamless Pipes | PERMITTED | SR4 MANDATORY | TABLE 14 9.7.2.6 |
REPARE BY WELDING OF Pipe BODY, PLATE AND SKELP | PERMITTED BY AGREEMENT | PROHIBITED | 5.3.2;9.7.6: B.1;B.2 |
CERTIFICATION | CERTIFICATES WHEN SPECIFIED PER SR15 | PROHIBITED | 4.3;9.7.4.4;9.7.6;B.1.2;B.4 |
TRACEABILITY | TRACEABLE ONLY UNTIL ALL TESTS ARE PASSED UNLESS SR15 IS SPECIFIED | CERTIFICATES (SR15.1) MANDATORY TRACEABLE AFTER COMPLETION OF TESTS (SR15.2) MANDATORY |
12.1 5.6 |
API 5L Specifications Covers Seamless and Welded pipe suitable for use in conveying gas, water, oil, and other liquefied media. The attached requirements cover our offering of API 5L 45th Ed, PSL 1Seamless and Welded; API 5L 45th Ed PSL 2 Seamless & Welded; and API 5L 45th Ed PSL2 Welded only.
Tensile Properties for Seamless and Welded API 5L SSC Tested Steel Pipe and Steel Seamless Pipe
tensile properties data for Seamless and Welded API 5L steel pipe API 5L 45th Ed PSL 1, PSL 2.
Testing Req for Seamless and Welded API 5L SSC Tested steel Pipe
Our API 5L Seamless Pipes hydrostatic and mechanical testing information for all sizes and grades covered by the specification.
Grade A, B, A25 | X56 through X80 | |
NPS 2-1/2 and smaller --Seamless and Welded, % | +20 -- 12.5 | +15 -- 12.5 |
NPS 3 --Seamless and Welded, % | +18 -- 12.5 | +15 -- 12.5 |
NPS 4 through 18 --Seamless and Welded, % | +15 -- 12.5 | +15 -- 12.5 |
NPS 20 and larger -- Welded, % | +17.5 -- 10.0 | +19.5 -- 8.0 |
NPS 20 and larger -- Seamless, % | +15.0 -- 12.5 | +17.5 -- 10.0 |
Paint-stenciled or die-stamped manufacturer’s name or mark, Spec 5L, size, weight per foot, grade, process of manufacture, type of steel, length (NPS 4 and larger only). Test pressure when higher than tabulated (NPS 2 and larger only).
Supplemental Annexes for API 5L SSC TestedSeamless and Welded steel Pipe
API Specification 5L contains 15 Supplemental Annexes that address special conditions and/or additional requirements.
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We provide API 5L SSC Tested SOUR Service Pipe in Grade B, X42, X46, X52, X56, X60, X65 with PSL1 and PSL2. We Carry Complete Range from 3/8" NB to 24" NB, wall Thicknesss upto 200 MM. Prosaic Steel and Alloys API 5L Grade B Pipe are known for its High Temperature and High Quality and Competitive Price.
Sabic Saudi Arabia) | Shell | ALBA (Saudi Arabia) | QAFCO(Qatar) | Maaden(Saudi Arabia) | KNPC(Kuwait) |
Kuwait Oil Company(Kuwait) | Qatar Petroleum(Qatar) | Petroleum Development Oman(Oman) | ADNOC(United Arab Emirates) | Orpic(Oman) | Takreer(Abu Dhabi) |
YASREF(Abu Dhabi) | Petrobras(Brazil) | Petronas(Malaysia) | NIOC(Iran) | NPDC(Nigeria) | Egyptian General petroleum Corporation(Egypt) |
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We Export API 5L X56 SSC Tested Pipe to Saudi Arabia, Iran, Iraq, United Arab Emirates, Qatar, Bahrain, Oman, Kuwait, Turkey, Egypt, Yemen, Syria, Israel, Jordan, Cyprus, Singapore, Malaysia, Indonesia, Thailand, Vietnam, South Korea, Japan, Sri Lanka, Maldives, Bangladesh, Mayanmar, Taiwan, Cambodia, Argentina, Bolivia, Brazil, Chile, Venezuela, Colombia, Ecuador, Guyana, Paraguay, Uruguay, United States of America, Canada, Mexico, Panama, Costa Rica, Puerto Rica, Trinidad And Tobago, Jamaica, Bahamas, Denmark, Russia, Norway, Germany, France, Italy, United Kingdom, Spain, Ukraine, Netherland, Belgium, Greece, Czech Republic, Portugal, Hungary, Albania, Austria, Switzerland, Slovakia, Finland, Ireland, Croatia, Slovenia, Malta, Nigeria, Algeria, Angola, South Africa, Libya, Egypt, Sudan, Equatorial Guinea, The Republic Of Congo, Gabon, Europe, Africa, Asia, North America, South America, Middle East, Far East.etc
Savoy Piping Inc. is a well known worldwide exporter of API 5L X56 SSC Tested Pipe is committed to provide each and every customer with the highest standard of customer service. We deals in API 5L X56 SSC Tested Pipe in India and Overseas, offering a wide range of API 5L X56 SSC Tested Pipes