THERMALLY INSULATIVE COMPOSITIONS FOR A CERAMIC COATING

Organization Name

Nanotech Inc.

Inventor(s)

Claudinei Calado Rezende of Spring TX (US)

Hani Taan of Spring TX (US)

THERMALLY INSULATIVE COMPOSITIONS FOR A CERAMIC COATING - A simplified explanation of the abstract

This abstract first appeared for US patent application 18158812 titled 'THERMALLY INSULATIVE COMPOSITIONS FOR A CERAMIC COATING

Simplified Explanation: A new hard ceramic coating with refractory properties is introduced as a replacement for traditional refractory materials, offering non-sacrificial, inorganic, and lightweight characteristics.

Key Features and Innovation:

• Non-sacrificial, fully inorganic ceramic coating
• Resists extreme temperatures and thermal cycles
• Thinner and lighter than conventional refractory materials
• Demonstrates advantageous thermal insulation properties
• High emissivity, low thermal conductivity, and high resistance mechanical properties

Potential Applications: The ceramic coating can be used in industries requiring high-temperature resistance, such as aerospace, automotive, and manufacturing.

Problems Solved: This technology addresses the need for a durable, lightweight, and thermally insulating coating for high-temperature applications.

Benefits:

• Improved thermal insulation
• Lightweight and thin design
• Resistance to extreme temperatures and thermal cycles

Commercial Applications: Potential commercial applications include coating components in jet engines, exhaust systems, and industrial furnaces.

Questions about Ceramic Coating: 1. How does the ceramic coating compare to traditional refractory materials in terms of durability? 2. What industries can benefit the most from using this innovative ceramic coating technology?

Frequently Updated Research: Ongoing research may focus on optimizing the composition of the ceramic coating for specific industrial applications.

Original Abstract Submitted

A new and innovative hard ceramic coating having refractory properties is provided. The ceramic coating may be used as a replacement for refractory materials. As opposed to polymer-based coatings that are sacrificial when exposed to extreme temperatures, the ceramic coating is a non-sacrificial, fully inorganic (e.g., free of organic components) coating that resists many thermal cycles. The ceramic coating is also thinner and lighter than conventional refractory materials the ceramic coating can replace. The ceramic coating demonstrates advantageous thermal insulation properties (e.g., low thermal conductivity) over a wide range of temperatures and when applied with minimal thickness. The ceramic coating also demonstrates high emissivity, low thermal conductivity, and high resistance mechanical properties, which are all desirable properties for use as a thermally insulating replacement coating for refractory materials.