PWA 1480

PWA 1480 is a first-generation single-crystal superalloy with excellent high-temperature strength, fatigue resistance, and outstanding creep performance at 980°C.

About PWA 1480 Superalloy

Name and Equivalent Name

PWA 1480 is a first-generation single-crystal nickel-based superalloy developed primarily for aerospace applications, particularly high-stress turbine blades. Although no direct equivalent name exists, it shares design principles with other first-generation single-crystal alloys like CMSX-2 and René N4.

PWA 1480 Basic Introduction

PWA 1480 is designed as a high-performance single-crystal superalloy with exceptional mechanical properties at elevated temperatures. It is widely used in turbine blades of jet engines, offering resistance to thermal fatigue and creep at temperatures exceeding 980°C.

The alloy’s composition emphasizes a balance of nickel, chromium, cobalt, and tantalum, contributing to its corrosion resistance, strength, and stability in extreme environments. Its single-crystal structure eliminates grain boundaries, improving mechanical performance and fatigue life under high-temperature conditions.

pwa-1480-single-crystal-superalloy-investment-casting-blades-manufacturer

Alternative Superalloys of PWA 1480

Alternatives to PWA 1480 include other first-generation single-crystal alloys like CMSX-2, René N4, and SRR 99. These superalloys exhibit similar performance characteristics but differ in composition and application ranges. Later-generation alloys such as CMSX-4 and René N5 offer improved creep resistance, though at a higher cost and complexity. PWA 1480 remains a reliable choice for aerospace components requiring a balance of performance, durability, and ease of manufacture.


PWA 1480 Design Intention

PWA 1480 was designed to address the need for single-crystal turbine blades to sustain high mechanical loads at elevated temperatures. Eliminating grain boundaries minimizes creep and fatigue cracking, significantly improving the durability of components operating at over 980°C. The high tantalum and chromium content enhances the material's oxidation resistance, ensuring long service life. With a focus on mechanical reliability and oxidation resistance, PWA 1480 meets the rigorous demands of jet engines and gas turbines.


PWA 1480 Chemical Composition

The chemical elements in PWA 1480 play critical roles in enhancing its performance. Nickel provides a stable matrix, while chromium offers oxidation resistance. Tantalum strengthens the matrix and increases creep resistance, and cobalt improves high-temperature stability. Aluminum contributes to the formation of protective oxide layers.

Element

Weight %

Nickel (Ni)

Balance

Chromium (Cr)

10%

Cobalt (Co)

5%

Molybdenum (Mo)

2%

Tungsten (W)

4%

Aluminum (Al)

5%

Tantalum (Ta)

12%

Hafnium (Hf)

1.5%


PWA 1480 Physical Properties

PWA 1480 exhibits superior mechanical strength at high temperatures, a high melting point, and excellent thermal conductivity, making it ideal for aerospace applications.

Property

Value

Density

8.69 g/cm³

Melting Point

1345°C

Thermal Conductivity

10.9 W/(m·K)

Modulus of Elasticity

212 GPa

Tensile Strength

1120 MPa


Metallographic Structure of PWA 1480 Superalloy

PWA 1480 is a nickel-based single-crystal superalloy with no grain boundaries, which prevents grain boundary sliding and minimizes creep deformation at high temperatures. The alloy contains a gamma (γ) matrix reinforced by gamma-prime (γ') precipitates. The γ' phase, consisting of nickel, aluminum, and tantalum, provides the alloy with high mechanical strength and resistance to plastic deformation.

The absence of grain boundaries significantly improves the alloy’s fatigue resistance. The fine dispersion of γ' precipitates ensures stability even under thermal cycling, making PWA 1480 ideal for use in high-performance turbine engines.


PWA 1480 Mechanical Properties

PWA 1480 offers excellent tensile and yield strength with high fatigue resistance. It maintains its mechanical integrity even at elevated temperatures, providing reliable performance.

Property

Value

Tensile Strength

~1200-1250 MPa

Yield Strength

~900 MPa

Creep Strength

High at 980°C

Fatigue Strength

Strong

Hardness (HRC)

35-45

Elongation

10-12%

Creep Rupture Life

~10,000 hours at 980°C


Key Features of PWA 1480 Superalloy

  1. High-Temperature Strength PWA 1480 retains excellent tensile strength up to 1250 MPa at elevated temperatures, ensuring reliable performance in jet engines and turbines.

  2. Creep Resistance Designed to operate under prolonged stress at 980°C, PWA 1480 exhibits minimal creep deformation and offers a creep rupture life of up to 10,000 hours.

  3. Fatigue Resistance The absence of grain boundaries and the fine γ' precipitate distribution provide exceptional resistance to fatigue, especially under thermal cycling.

  4. Oxidation Resistance The alloy’s 10% chromium content enhances oxidation resistance, protecting components exposed to high temperatures and corrosive environments.

  5. Thermal Stability With a melting point of 1345°C and excellent thermal conductivity, PWA 1480 maintains stability in demanding aerospace applications, such as turbine blades.

PWA 1480 Superalloy’s Machinability

PWA 1480 is suitable for Vacuum Investment Casting due to its high-temperature resistance, enabling precise and defect-free parts. However, precise temperature control during casting is required to avoid defects.

The alloy is ideal for Single Crystal Casting since it eliminates grain boundaries, prevents creep, and improves fatigue resistance under high stress and temperature conditions.

PWA 1480 is unsuitable for Equiaxed Crystal Casting as its design focuses on single-crystal structures, which are more resistant to creep than equiaxed materials.

The alloy is generally not used in Superalloy Directional Casting because its performance is optimized for fully single-crystal structures, offering better mechanical stability.

PWA 1480 is incompatible with powder metallurgy turbine disc applications, as solid casting processes are required for optimal microstructural integrity.

The alloy is not used in Superalloy Precision Forging due to the difficulty in shaping single-crystal materials without introducing microstructural inconsistencies.

PWA 1480 is not ideal for Superalloy 3D Printing, as the single-crystal microstructure is challenging to replicate through additive manufacturing processes.

PWA 1480 can undergo CNC Machining to achieve tight tolerances, but machining requires specialized tooling due to its hardness and resistance to wear.

It is suitable for Superalloy Welding in certain applications, though welding single-crystal alloys is challenging and typically avoided to prevent cracking.

The alloy benefits from Hot Isostatic Pressing (HIP), which enhances its microstructural integrity, eliminating porosity and improving mechanical properties.


PWA 1480 Superalloy Applications

In the Aerospace and Aviation industry, PWA 1480 is primarily used in turbine blades for jet engines, where high strength and thermal fatigue resistance are critical.

For Power Generation, the alloy is used in gas turbines, contributing to reliable power delivery under harsh operating conditions.

In the oil and gas sector, PWA 1480 is applied to high-temperature valves and components for gas turbines, where durability and corrosion resistance are essential.

The Energy industry benefits from PWA 1480’s reliability in turbines for conventional and renewable power plants.

In the Marine industry, the alloy is used in turbine components and propulsion systems, ensuring performance in corrosive environments.

For Mining, PWA 1480 offers durability in components exposed to abrasive environments, such as high-pressure pumps.

In the automotive industry, it is found in motorsports and high-performance engines, requiring superior thermal stability and mechanical strength.

Due to its corrosion resistance, the Chemical Processing industry benefits from PWA 1480 in high-temperature reactors and heat exchangers.

In Pharmaceutical and Food applications, the alloy is used where high-temperature sterilization or corrosion resistance is needed.

The Military and Defense sector uses PWA 1480 in jet engines and advanced propulsion systems for fighter aircraft.

The alloy is also applied in the Nuclear industry for turbines and reactors, leveraging its resistance to thermal fatigue and radiation.


When to Choose PWA 1480 Superalloy

PWA 1480 is ideal when high performance is required at extreme temperatures. It is the go-to material for custom superalloy parts such as jet engine blades, gas turbines, and high-temperature components that demand superior creep resistance and fatigue life. It excels in applications where thermal stability, oxidation resistance, and mechanical strength must be maintained without compromise. If you need long-lasting, high-performance components tailored to specific industry needs, PWA 1480 provides unmatched reliability, especially for applications in aviation, energy, and high-temperature manufacturing environments. Explore options for custom superalloy parts here.

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