Boride

Key Features:

Measured Hardness: Standard tests show hardness values up to 2 500 HV. This outcome qualifies the material for uses requiring high wear resistance and long-term operational consistency.

High Temperature Stability: Thermal analysis confirms that the materials maintain structural integrity up to 1 200 °C. They continue to perform under elevated temperature conditions.

Precision Manufacture: Production methods achieve dimensional tolerances within 0.01 mm. This process ensures reliable performance in technical components.

Versatile Applications: Borides are used in applications ranging from precision tool components to aerospace parts. Standardised tests have recorded a wear reduction of 37% in some cases.

Industries We Supply:

Manufacturing: Borides are incorporated into precision manufacturing. They support extended service life for tools and machine components.

Aerospace: In aerospace, borides contribute to the production of lightweight components that perform reliably under mechanical stress. Testing confirms consistent behaviour.

Mechanical Engineering: Borides are applied in components subject to abrasion and high loads. Laboratory measurements indicate improved durability and reduced wear.

Research and Development: Research institutions and industrial laboratories use borides in material studies. Controlled experiments have verified accurate material behaviour.

Reasons to Choose Our Borides:

Quality Assurance: Our borides undergo standardised tests for hardness, thermal stability, and dimensional accuracy, thereby meeting industry specifications.

Technical Expertise: Experts from Stanford Advanced Materials (SAM) provide guidance based on quantitative analysis. They assist in selecting the appropriate material for specific applications.

Sustainability: Lifecycle assessments confirm that manufacturing processes yield components with an average operational durability of 10 000 hours. This data supports long-term sustainability.