15CrMoG seamless steel pipe is a special alloy steel pipe widely used in high-pressure and high-temperature environments. The “15″ in its name represents a carbon content of approximately 0.15%, “Cr” and “Mo” represent chromium and molybdenum, respectively, and “G” is a special designation for boiler steel. This material, with its excellent heat resistance, creep resistance, and high-temperature strength, has become a key material in industries such as power generation, petrochemicals, and boiler manufacturing.

First, the material characteristics and chemical composition of the 15CrMoG seamless steel pipe.
The chemical composition of 15CrMoG seamless steel pipe is the foundation of its performance. Its typical composition is: carbon: 0.12%~0.18%, silicon: 0.17%~0.37%, manganese: 0.40%~0.70%, chromium: 0.80%~1.20%, molybdenum: 0.45%~0.60%, with sulfur and phosphorus content strictly controlled below 0.035%. The addition of chromium significantly improves the steel’s oxidation resistance and corrosion resistance, while molybdenum enhances the material’s high-temperature strength and creep resistance, allowing it to maintain stable mechanical properties even during long-term operation below 580℃.
In terms of mechanical properties, 15CrMoG seamless steel pipes typically have a tensile strength of≥440MPa, a yield strength of≥295MPa, and an elongation of≥22%. Its microstructure is pearlite + ferrite; after normalizing and tempering heat treatment, the grains are more uniform, further improving its high-temperature resistance. Compared to ordinary carbon steel, its strength degradation rate at high temperatures is about 30% lower, making it an ideal choice for manufacturing superheater and reheater pipes in supercritical boilers.

Second, the production process and technical challenges of 15CrMoG seamless steel pipes.
The production of 15CrMoG seamless steel pipes requires multiple precision processes, including smelting, piercing, rolling, and heat treatment. First, electric arc furnace or converter smelting is used, followed by LF furnace refining and VD vacuum degassing to ensure the purity of the molten steel. In the hot rolling stage, steel billets are formed into tubes using a Mannesmann piercing mill, which are then rolled into finished tubes using a continuous rolling mill. Temperature control is particularly critical; the piercing temperature must be maintained at 1200±20℃, and the final rolling temperature must not be lower than 900℃ to avoid internal cracks and surface defects.
The cold working stage employs cold rolling or cold drawing processes, improving dimensional accuracy through a deformation rate of up to 80%. Heat treatment utilizes a dual process of normalizing (900~930℃) + tempering (680~720℃) to eliminate processing stress and ensure uniform carbide precipitation. It is noteworthy that 15CrMoG seamless steel pipes are sensitive to cooling rates, requiring segmented controlled cooling technology to prevent martensitic transformation that increases brittleness. According to GB5310-2017 standard, 100% of finished products must pass eddy current testing and ultrasonic testing to ensure the absence of defects such as inclusions and porosity.

Third, Core Application Areas of 15CrMoG Seamless Steel Pipes.
1. Power Industry: As the “blood vessels” of supercritical boiler units, 15CrMoG seamless steel pipes are widely used in superheater piping at steam temperatures up to 540℃. A 600MW unit requires approximately 200 tons of this material’s piping, which has a pressure resistance exceeding 28MPa and a service life exceeding 100,000 hours.
2. Petrochemical Industry: In hydrocracking reactors and cracking units, this material resists H₂S and CO₂ corrosion. A refinery’s hydrocracking unit uses Φ273×28mm pipes, which have operated continuously for 5 years at 450℃ and 15MPa without exhibiting hydrogen embrittlement.
3. Nuclear Power Industry: As a secondary loop auxiliary piping material, its radiation resistance is superior to that of 304 stainless steel. In the Qinshan Nuclear Power Plant Phase II project, 15CrMoG seamless steel pipes account for 18% of the piping system.

Fourth, Industry Standards and Quality Control of 15CrMoG Seamless Steel Pipes
Major domestic and international standards have strict regulations for 15CrMoG:
China’s GB5310-2017 “Seamless Steel Tubes for High-Pressure Boilers” requires each tube to undergo a hydrostatic test (test pressure = 2.5 × working pressure).
The US ASME SA335 standard requires chromium-molybdenum steel to undergo a Charpy V-notch impact test.
The EU EN10216-2 standard requires the provision of high-temperature creep strength data (typically requiring a fracture stress ≥ 80 MPa after 100,000 hours).
In actual procurement, the following quality documents should be given special attention:
1. Third-party testing reports (including spectral analysis and hardness testing)
2. Heat treatment curve records
3. Original non-destructive testing spectra
4. Material traceability code (allowing for querying the smelting furnace number)

Fifth, Market Status and Development Trends of 15CrMoG Seamless Steel Pipes.
The global market size for 15CrMoG seamless steel pipes is estimated at approximately 500,000 tons in 2024, with China accounting for 65%. Some enterprises have achieved full coverage of specifications from Φ16 to Φ762mm, with some products exported to Southeast Asia and the Middle East. As ultra-supercritical units develop towards 630℃, a new improved 15CrMoG (with trace amounts of V and Nb) is currently in the testing phase and is expected to be mass-produced in 2026. Regarding use and maintenance, it is recommended to conduct wall thickness testing every 3 years (paying special attention to elbows) and consider replacement when the carbide spheroidization level reaches level 4. During storage, the relative humidity of the warehouse should be maintained at ≤60% to avoid stress corrosion caused by chloride ions.

As a “backbone” of industrial high-temperature pipelines, the technological upgrade of 15CrMoG seamless steel pipes will continue to drive the development of energy equipment towards high efficiency and environmental protection. In the future, with the popularization of intelligent manufacturing, its production process will increasingly utilize digital twin technology to achieve quality prediction, further reducing the defect rate to below 0.2%.