Our GH3536 high-temperature bar is a rockstar for furnace and power generation applications. This nickel-chromium-molybdenum alloy, with a boost from tungsten, is designed to handle extreme heat up to 980°C (1800°F) while shrugging off oxidation and corrosion. It’s the perfect fit for gas turbine components, furnace rollers, and power plant heat exchangers that need to keep performing under intense conditions. With high tensile strength and excellent creep resistance, GH3536 ensures your components stay strong and reliable, no matter how hot things get.
We craft GH3536 with precision, using solution treatment to make it easier to work with and age-hardening to maximize its strength and durability. Whether you’re building industrial furnaces or high-performance turbine parts, our bars deliver consistent quality and toughness. They’re versatile enough for forging, machining, or even additive manufacturing, making GH3536 a go-to for industries that demand the best in high-temperature performance.
For more details, pls directly contact us.
The high-temperature alloy market is heating up, driven by the need for materials that can handle extreme conditions in power generation, aerospace, and industrial furnaces. As power plants push for higher efficiency with ultra-supercritical systems, and aerospace demands lighter, stronger components, alloys like GH3536 are in high demand. The global superalloy market is expected to grow steadily, fueled by rising energy demands and advancements in turbine technology. Industrial furnaces, especially in petrochemical and steel industries, also rely on materials that resist creep and oxidation under prolonged heat.
Additive manufacturing is changing the game, allowing complex parts to be made with less waste, while sustainability trends push for more efficient material use. Challenges like high machining costs and the need for specialized tools persist, but the demand for durable, high-temperature alloys keeps the market outlook strong. GH3536 is well-positioned to meet these needs, offering top-tier performance for critical applications.
Comparison Table
|
Parameter |
GH3536 High-Temperature Bar |
Competitor Alloy |
|---|---|---|
|
Max Operating Temperature |
Up to 980°C (1800°F) |
Up to 900°C (1652°F) |
|
Oxidation Resistance |
Excellent, with Cr and Mo |
Good |
|
Creep Resistance |
High, enhanced by tungsten |
Moderate |
|
Tensile Strength |
900-1150 MPa |
800-1000 MPa |
|
Machinability |
Challenging, needs specialized tools |
Easier |
|
Corrosion Resistance |
Strong in harsh environments |
Moderate |
|
Applications |
Furnace parts, turbine components |
General high-temp parts |
|
Cost Efficiency |
Competitive for performance |
Lower initial cost |
GH3536 high-temperature bars shine in environments where heat and stress are relentless. In power generation, they’re used for gas turbine blades, heat exchangers, and boiler components that face high temperatures and corrosive gases. Industrial furnaces rely on GH3536 for rollers, radiant tubes, and burners that need to withstand prolonged heat exposure. In aerospace, it’s a go-to for turbine discs and exhaust components that demand strength and oxidation resistance. Petrochemical plants also use GH3536 for equipment exposed to high heat and aggressive chemicals, ensuring long-term reliability across diverse applications.
|
Item |
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.
When it comes to high-temperature alloys, our GH3536 bar stands out from the pack. While other materials might struggle with creep or oxidation at high temperatures, our GH3536 delivers exceptional performance up to 980°C, thanks to its optimized nickel-chromium-molybdenum-tungsten composition. This means your components last longer, perform better, and require less maintenance, saving you both time and money.
Our advantage comes from our focus on quality and innovation. We use cutting-edge manufacturing processes, like vacuum melting and tailored heat treatments, to ensure every GH3536 bar meets the highest standards for consistency and performance. Our team works closely with you to customize solutions, whether you need precision-forged parts or complex 3D-printed components. Plus, our pricing is competitive, delivering top-tier performance without the hefty price tag. With GH3536, you’re getting a material that’s tough, reliable, and ready to tackle the most demanding furnace and power generation challenges.
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.
Client Visits
Building Stronger Partnerships
We support all kinds of testing:
FAQs:
-
What is GH3536 high-temperature bar used for?
It’s built for furnace components, gas turbine parts, and power generation systems that operate under extreme heat and stress. -
How does GH3536 perform in high-temperature environments?
Its nickel-chromium-molybdenum blend, with added tungsten, ensures excellent strength and stability up to 980°C (1800°F). -
Is GH3536 resistant to oxidation and corrosion?
Yes, it offers outstanding oxidation resistance and holds up well in corrosive environments like those in power plants. -
Which industries rely on GH3536 bars?
Power generation, aerospace, industrial furnaces, and petrochemical industries use it for its heat and corrosion resistance. -
How easy is it to machine GH3536?
It’s challenging due to its high strength, but with specialized tools and techniques, it can be machined effectively. -
What are the key mechanical properties of GH3536?
It has high tensile strength (900-1150 MPa), excellent creep resistance, and strong fatigue resistance at elevated temperatures. -
How is GH3536 processed for optimal performance?
It’s typically solution-treated and age-hardened to enhance strength and maintain workability for complex components. -
Why choose GH3536 over other high-temperature alloys?
It offers a superior combo of heat resistance, creep strength, and durability, making it ideal for demanding furnace and power applications.