Precision ceramic structural components and their applications
Ceramics offer numerous advantages across a variety of applications in multiple markets. In vehicle and automotive engineering, electronics, energy and environment, as well as equipment and mechanical engineering, precision ceramics play a crucial role in enhancing safety, cost efficiency, and comfort in vehicles and automotive engineering. Lu Hai Technology will recommend reasonable and cost-effective production methods based on the application field, material geometric characteristics, and quantity of the customer's products.
Precision Ceramic Components: Features and Advantages
High mechanical strength
High tensile strength and impact resistance
-- Exceptional wear resistance
-- Excellent thermal conductivity
Low thermal expansion
Thermal shock resistance
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High Temperature Co-Fired Ceramic (HTCC) Technology
What is HTCC technology?
Utilizing multilayer ceramic substrate technology, as these multilayer substrates are co-sintered at a high temperature of 1600°C using alumina insulating materials and conductive materials (Mo, W, Mo-Mn), they are classified as High Temperature Co-Sintered Ceramics (HTCC) to differentiate them from the later-developed Low Temperature Co-Sintered Ceramics (LTCC).
HTCC (High Temperature Co-fired Ceramic) typically employs metals like tungsten, molybdenum, and manganese with high melting points. According to circuit design specifications, these metals are printed onto green bodies of alumina, aluminum nitride, or mullite ceramics (less commonly used), then stacked and sintered together at temperatures ranging from 1650 to 1850°C.
