Tungsten-nickel-iron alloy (W-Ni-Fe alloy) is a high-density alloy with tungsten as its matrix, allowing for a balance of density, strength, toughness, and cost through the adjustment of the nickel-iron ratio or the addition of trace elements. It is widely used in aerospace, defense, medical devices, and other fields. The alloy’s material composition includes tungsten, nickel, iron, carbon, and other elements.

Tungsten-nickel-iron alloy boasts high density, high tensile strength, excellent radiation absorption, and good processability, making it widely applicable in aerospace counterweights, armor-piercing projectile cores, nuclear radiation shielding, and medical equipment protection. Beyond tungsten content, powder characteristics, production processes, and process parameters, the nickel-iron ratio is another key factor influencing its performance.

Tungsten is the core component of tungsten-nickel-iron alloy, imparting exceptional counterweight performance through its high density of 19.35 g/cm³. It also enhances the alloy’s strength and hardness via solid-solution strengthening and particle dispersion strengthening, while optimizing its radiation absorption capacity, making it an ideal choice for high-performance shielding materials.

Tungsten-nickel-iron alloy is a material with tungsten as its base, incorporating nickel and iron, where tungsten content typically ranges from 90% to 98%, and the nickel-to-iron ratio is commonly 7:3 or 1:1. It exhibits high density, high strength, and excellent radiation shielding capabilities, finding wide use in counterweights and shielding applications. However, its performance is not fixed and is influenced by factors such as composition ratio, raw material quality, forming process, and heat treatment parameters.

In the expansive realm of materials science, tungsten-nickel-iron alloy garners significant attention for its unique properties and broad applications. As the name suggests, it is an alloy based on tungsten, with nickel and iron added, typically in a nickel-to-iron ratio of 7:3 or 1:1, and tungsten content ranging from 90% to 98%. This composition endows it with a host of exceptional characteristics.

In the vast landscape of modern industry, tungsten-nickel-iron alloy stands out as a multifaceted material due to its unique properties, playing a pivotal role across numerous fields. From high-precision equipment in aerospace to robust tools in oil drilling, from protective components in medical devices to precision parts in the automotive industry, this alloy is ubiquitous.

Tungsten-nickel-iron alloy, composed of tungsten, nickel, iron, and other elements, features high strength, high hardness, excellent corrosion resistance, and radiation shielding capabilities. It is widely used in aerospace, aviation, military, and electronics fields, such as for manufacturing counterweights, shielding components, and high-temperature structural parts. Common production methods include powder metallurgy, metal injection molding, and chemical co-precipitation.

The physical properties of tungsten-nickel-iron alloy include high strength, good ductility, high hardness, wear resistance, and a low thermal expansion coefficient, while its chemical properties encompass excellent corrosion resistance, high-temperature oxidation resistance, chemical stability, and erosion resistance. These chemical properties arise from the synergistic effects of the constituent elements and the alloy’s microstructural characteristics.

Tungsten-nickel-iron alloy is a material with tungsten as the matrix (typically 90%–98% tungsten content), formed by adding nickel, iron, and other elements. Its physical properties stem from the synergistic effect of tungsten’s high hardness and the toughness of the nickel-iron binder phase, which can be optimized by adjusting composition ratios and preparation processes.

The density of tungsten-nickel-iron alloy, typically ranging from 17.0 to 18.5 g/cm³, is a critical factor influencing its application scenarios. This high-density characteristic profoundly impacts the alloy’s use across functional realization, structural design, and scenario adaptability.