CO11729 Cobalt Based Alloy Plate CoCrWNiC Plate (694)

Cobalt Based Alloy Plate CoCrWNiC Plate (694) Description

Cobalt Based Alloy Plate CoCrWNiC Plate (694) is a specialised cobalt alloy that integrates controlled proportions of chromium, tungsten, nickel, and carbon. The alloy composition is engineered to optimise mechanical properties such as tensile and yield strength whilst ensuring a stable microstructure. Its composition is suited for applications requiring consistent performance under high thermal and mechanical loads, and it supports processes where dimensional stability is critical.

Cobalt Based Alloy Plate CoCrWNiC Plate (694) Characteristics

Chemical Composition (Wt%)

*The above product information is based on theoretical data and is for reference only. Actual specifications may vary.

Cobalt Based Alloy Plate CoCrWNiC Plate (694) Applications

1.       Industrial Manufacturing
   - Used as a structural component in heavy machinery to achieve enhanced load-bearing capacity by leveraging its balanced alloy composition.

2.       Aerospace Components
   - Applied as engine casing parts to achieve thermal stability and controlled expansion by leveraging its microstructural consistency.

3.       Chemical Processing Equipment
   - Served as corrosion-resistant liners in reactor vessels to achieve prolonged service life by leveraging its chemically inert properties.

Cobalt Based Alloy Plate CoCrWNiC Plate (694) Packing

The alloy plate is packaged with corrosion-inhibiting wraps and cushioned supports to minimise mechanical damage and surface degradation. It is stored in a climate-controlled container to maintain stable temperature and low humidity. Anti-contamination measures are incorporated during packing, and customised packaging options are available to meet specific storage and shipping requirements.

Additional Information

Cobalt alloys are integral in applications requiring high mechanical strength and stability at elevated temperatures. The interplay of cobalt with elements such as chromium, tungsten, and nickel enables control over grain structure and phase distribution, critical for predictable performance in structural applications. Scientific advancements in alloying and thermal treatments continue to refine these materials for industry-specific demands.

Understanding the fundamentals of metallurgical processes and the specific roles of alloying elements can assist in selecting the appropriate material for a given application. This knowledge is essential for researchers and engineers aiming to optimise manufacturing processes and enhance the longevity of components in industrial environments.