We’re proud to introduce our GH3536 nickel-based alloy tube, a game-changer for aerospace applications where extreme temperatures and harsh conditions are the norm. This high-performance alloy is engineered to deliver unmatched strength, durability, and resistance, making it the go-to material for critical components in aerospace and beyond. Let’s dive into what makes GH3536 stand out, explore its applications, and look at the industry trends driving its demand.
What is GH3536 Alloy?
GH3536 is a nickel-based superalloy packed with chromium and molybdenum, designed to thrive in high-temperature, high-stress environments. Its face-centered cubic structure, enhanced by solid-solution strengthening, gives it exceptional creep resistance and mechanical strength up to 900°C (and even 1080°C for short bursts). The alloy’s composition ensures a robust oxide layer, protecting it from oxidation and corrosion, even in the toughest conditions. Whether it’s fabricated through traditional methods or cutting-edge additive manufacturing, GH3536 delivers precision and reliability for complex parts.
Our GH3536 tubes are crafted with advanced powder metallurgy and optimized for processes like laser powder bed fusion (LPBF). This allows us to produce intricate geometries with minimal defects, ensuring high performance and a smooth surface finish. Plus, the alloy can be age-hardened to fine-tune its strength and ductility, giving you flexibility for specific project needs.
Industry Applications
Our GH3536 alloy tubes shine in aerospace, where they’re used for critical hot-end components like turbine blades, combustors, and gas turbine parts. These parts face blistering temperatures and intense stress, and GH3536’s ability to resist creep, thermal fatigue, and oxidation makes it a perfect fit. Beyond aerospace, this alloy is a star performer in power generation (think gas turbines), oil and gas (for high-temperature pipelines), and chemical processing (where corrosion resistance is key). Its versatility also makes it ideal for both new part production and repair of worn components, boosting efficiency and durability.
Industry Trends Driving Demand
The aerospace industry is pushing the boundaries of performance, and materials like GH3536 are at the forefront. With global demand for fuel-efficient, high-performance aircraft soaring, manufacturers are leaning on advanced alloys to lightweight parts without sacrificing strength. Additive manufacturing is a big trend, and GH3536’s excellent printability makes it a favorite for creating complex, near-net-shape components that traditional methods can’t match. The rise of sustainable aviation is also driving demand for materials that can handle higher operating temperatures to improve engine efficiency.
Another trend is the shift toward longer-lasting, low-maintenance components. GH3536’s superior oxidation and corrosion resistance mean fewer replacements and repairs, saving time and costs. The global aerospace market is projected to grow steadily, with a focus on next-gen engines and sustainable technologies, and our alloy is perfectly positioned to meet these needs.
Item | A-286 | Nimonic80A | Nimonic 90 | GH1140 | GH3625 | GH3536 | GH4169 |
C | ≤0.08 | ≤0.1 | ≤0.13 | 0.06-0.12 | ≤0.1 | 0.05-0.15 | ≤0.08 |
Mn | ≤2 | ≤1 | ≤1 | ≤0.7 | 3.14-4.15 | -- | ≤0.35 |
Fe | rest | ≤3 | ≤1.5 | rest | ≤0.5 | -- | rest |
P | ≤0.04 | ≤0.02 | -- | ≤0.025 | -- | -- | -- |
S | ≤0.03 | ≤0.015 | ≤0.015 | ≤0.015 | -- | -- | ≤0.01 |
Si | ≤1 | ≤1 | ≤1 | ≤0.8 | -- | -- | ≤0.35 |
Cu | -- | -- | ≤0.2 | -- | -- | -- | ≤0.3 |
Ni | 24-27 | rest | -- | 35-40 | rest | rest | 50-55 |
Co | -- | ≤2 | 15-21 | -- | ≤1.00 | 0.5-2.5 | ≤1.00 |
Al | ≤0.35 | 1-1.8 | 1-2 | 0.2-0.6 | ≤0.4 | ≤0.5 | 0.2-0.8 |
Ti | 1.9-2.35 | 1.8-2.7 | 2-3 | 0.7-1.2 | ≤0.4 | ≤0.15 | 0.7-1.15 |
Cr | 13.5-16 | 18-21 | 18-21 | 20-23 | 20-23 | 20.5-23 | 17-21 |
Nb | -- | -- | -- | -- | -- | -- | 4.75-5.5 |
Mo | 1-1.5 | -- | -- | 2-2.5 | 8-10 | 8-10 | 2.8-3.3 |
B | 0.001-0.1 | ≤0.008 | ≤0.02 | -- | -- | -- | -- |
V | 0.1-0.5 | -- | -- | -- | -- | -- | -- |
W | -- | -- | -- | 1.4-1.8 | -- | 0.2-1 | -- |
Zr | -- | ≤0.15 | ≤0.15 | -- | -- | -- | -- |
Pb | -- | -- | ≤0.002 | -- | -- | -- | -- |
Ce | -- | -- | -- | ≤0.05 | -- | -- | -- |
Size Range | |
Wire | 0.5-7.5mm |
Rod/Bar | 8.0-200mm |
Strip | (0.50-2.5)*(5-180)mm |
Tube | custom made |
| Plate | custom made |
For more details, pls directly contact us.
We’ve fine-tuned our GH3536 alloy tubes to outperform the competition. Here’s why we stand out:
Superior Quality: Our tubes are manufactured with precision, achieving near-full density (98.8%) and minimal defects like pores or cracks, ensuring top-notch performance.
Advanced Manufacturing: We leverage state-of-the-art LPBF technology to produce complex, lightweight parts with excellent surface finish, giving you an edge in design flexibility.
Tailored Performance: Our GH3536 can be heat-treated to optimize strength and ductility, letting you customize it for your specific application.
Unmatched Durability: With exceptional creep resistance and oxidation protection, our alloy tubes are built to last in the harshest environments, reducing downtime and maintenance costs.
Industry Expertise: We’ve got years of experience supplying high-performance alloys to aerospace leaders, so we know what it takes to meet your standards.
Unlike other alloys that struggle with high-temperature strength or printability, our GH3536 delivers a rare balance of toughness, corrosion resistance, and manufacturability. We’ve seen competitors’ materials fall short in extreme conditions, but our alloy consistently performs, whether it’s in a jet engine or a chemical reactor.
Parameter | GH3536 Alloy | Other Nickel-Based Alloys | Stainless Steel |
|---|---|---|---|
Max Service Temperature | Up to 900°C (long-term), 1080°C (short-term) | Up to 800–850°C | Up to 650–750°C |
Oxidation Resistance | Excellent (Cr, Mo oxide layer) | Good to moderate | Moderate to low |
Creep Strength | High, resists deformation at 900°C | Moderate to high | Low at high temperatures |
Corrosion Resistance | Superior in harsh environments | Good in specific conditions | Moderate, varies by grade |
Additive Manufacturing | Excellent printability, low porosity | Varies, often higher porosity | Limited, less suited for complex parts |
Tensile Strength (Room Temp) | ~823 MPa | ~700–800 MPa | ~500–600 MPa |
Elongation (Room Temp) | ~22.3% | ~15–20% | ~20–40% |
Applications | Aerospace, power generation, oil & gas | Aerospace, industrial | General industrial, lower temp applications |
Our GH3536 nickel-based alloy tubes are engineered for the toughest challenges in aerospace and high-temperature applications. With unmatched strength, corrosion resistance, and compatibility with advanced manufacturing, they’re the ideal choice for pushing the limits of performance. As the aerospace industry evolves toward efficiency and sustainability, we’re ready to support your projects with a material that delivers every time. Ready to elevate your components? Our GH3536 alloy tubes are here to make it happen.
About Us:
Our 12,000㎡ factory is equipped with complete capabilities for research, production, testing, and packaging. We strictly adhere to ISO 9001 standards in our production processes, with an annual output of 1,200 tons. This ensures that we meet both quantity and quality demands. Furthermore, all products undergo rigorous simulated environment testing including high temperature, high pressure, and corrosion tests before being dispatched, ensuring they meet customer specifications.For all our clients, we offer timely and multilingual after-sales support and technical consulting, helping you resolve any issues swiftly and efficiently.
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FAQs:
What is GH3536 alloy used for?
GH3536 is used for high-temperature aerospace parts like turbine blades, combustors, and gas turbine components, thanks to its strength and resistance to extreme conditions.What temperatures can GH3536 withstand?
It performs reliably up to 900°C for long-term use and can handle short-term exposure up to 1080°C.How does GH3536 resist corrosion?
Its high chromium and molybdenum content creates a protective oxide layer, shielding it from oxidation and corrosion in harsh environments.Why choose GH3536 for additive manufacturing?
Its optimized powder form enables complex geometries with low porosity, ideal for 3D-printed aerospace parts.What are the mechanical benefits of GH3536?
It offers excellent creep resistance, thermal fatigue life, and high strength, even at elevated temperatures.How does GH3536 compare to other alloys?
It outperforms many stainless steels and traditional nickel alloys in high-temperature strength and oxidation resistance.What industries use GH3536?
Primarily aerospace, but also power generation, oil and gas, and chemical processing for high-stress, high-heat applications.Can GH3536 be heat-treated?
Yes, it can be age-hardened to enhance strength and ductility, tailoring it to specific performance needs.