Language
| Quantity: | |
|---|---|
Production Description
A pneumatic lift emulsifier combines a pneumatic lifting system with high-shear emulsification technology. Its core principles are as follows:
Working Principle
A pneumatic cylinder drives the bracket up and down, while an air pump or solenoid valve controls the lift height. Precise positioning can be achieved by rotating the air valve or pressing a button.
The base is typically equipped with casters for easy movement and adjustment.
High-Shear Emulsification Process
The rotor rotates at high speed (up to 3400 rpm) within the stator cavity, creating a vacuum that draws material into the shear chamber from both upper and lower feed ports.
In the narrow gap (approximately 0.5-0.7 mm) between the rotor and stator, the material undergoes shearing, centrifugal extrusion, impact tearing, and other combined forces, enduring hundreds of thousands of mechanical shocks per minute, achieving nanoscale emulsification.
Production Description
A pneumatic lift emulsifier combines a pneumatic lifting system with high-shear emulsification technology. Its core principles are as follows:
Working Principle
A pneumatic cylinder drives the bracket up and down, while an air pump or solenoid valve controls the lift height. Precise positioning can be achieved by rotating the air valve or pressing a button.
The base is typically equipped with casters for easy movement and adjustment.
High-Shear Emulsification Process
The rotor rotates at high speed (up to 3400 rpm) within the stator cavity, creating a vacuum that draws material into the shear chamber from both upper and lower feed ports.
In the narrow gap (approximately 0.5-0.7 mm) between the rotor and stator, the material undergoes shearing, centrifugal extrusion, impact tearing, and other combined forces, enduring hundreds of thousands of mechanical shocks per minute, achieving nanoscale emulsification.
