METHOD FOR SYNTHESIZING NANO-SIZED ZEOLITE BETA

Organization Name

Saudi Arabian Oil Company

Inventor(s)

Lianhui Ding of Dhahran (SA)

METHOD FOR SYNTHESIZING NANO-SIZED ZEOLITE BETA - A simplified explanation of the abstract

This abstract first appeared for US patent application 18059705 titled 'METHOD FOR SYNTHESIZING NANO-SIZED ZEOLITE BETA

Simplified Explanation

The method described in the patent application involves synthesizing a nano-sized zeolite beta by mixing alumina and tetraethylammonium hydroxide to form an aluminum solution, mixing silica, additional TEAOH, and water to form a silica slurry, adding the aluminum solution into the silica slurry to form an aluminosilicate gel, transferring the gel to an autoclave operated at 120°C to 160°C for 2 to 4 days at a rotational speed of 60 to 100 rotations per minute to form a zeolite precursor colloid, washing the colloid with water, drying it, and calcining it to form the nano-sized zeolite beta.

• Mixing alumina and tetraethylammonium hydroxide to form an aluminum solution
• Mixing silica, additional TEAOH, and water to form a silica slurry
• Adding the aluminum solution into the silica slurry to form an aluminosilicate gel
• Transferring the gel to an autoclave operated at 120°C to 160°C for 2 to 4 days at a rotational speed of 60 to 100 rotations per minute to form a zeolite precursor colloid
• Washing the colloid with water
• Drying the colloid
• Calcining the colloid to form the nano-sized zeolite beta

Potential Applications

The nano-sized zeolite beta can be used in catalysis, adsorption, and separation processes in various industries such as petrochemical, environmental, and pharmaceutical.

Problems Solved

This method provides a way to efficiently synthesize nano-sized zeolite beta, which can offer improved performance in catalytic reactions, adsorption processes, and separation techniques compared to conventional zeolites.

Benefits

The nano-sized zeolite beta produced using this method has a high surface area, uniform pore size distribution, and enhanced thermal stability, making it a valuable material for a wide range of applications.

Potential Commercial Applications

"Nano-sized Zeolite Beta Synthesis Method for Enhanced Catalysis and Adsorption"

Possible Prior Art

There may be prior art related to the synthesis of zeolites using different methods or precursors. Further research and patent searches would be needed to identify specific prior art in this field.

Unanswered Questions

What are the specific industries that could benefit the most from using nano-sized zeolite beta?

The article mentions various industries where the nano-sized zeolite beta can be applied, but it does not provide specific examples or details on the potential impact in each industry.

Are there any limitations or challenges associated with the synthesis method described in the patent application?

While the method outlines a detailed process for synthesizing nano-sized zeolite beta, it does not address any potential limitations, scalability issues, or challenges that may arise during the production process.

Original Abstract Submitted

Methods for synthesizing a nano-sized zeolite beta are described. The method may include mixing alumina and tetraethylammonium hydroxide to form an aluminum solution; mixing silica, additional TEAOH, and water to form a silica slurry; and adding the aluminum solution into the silica slurry and mixing to form an aluminosilicate gel. The method may further include transferring the aluminosilicate gel to an autoclave operated at 120° C. to 160° C. for 2 to 4 days at a rotational speed of 60 to 100 rotations per minute to form a zeolite precursor colloid; washing the zeolite precursor colloid with water to form a washed colloid; drying the washed colloid at 80° C. to 150° C. for 6 to 24 hours to form a zeolite precursor; and calcining the zeolite precursor at 400° C. to 650° C. for 2 to 8 hours to form the nano-sized zeolite beta.