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Disperser Description
High-Pressure Homogenizer Technical Overview
A high-pressure homogenizer (HPH) is an industrial device that utilizes ultra-high pressure (up to 2,000+ bar) to achieve nanoscale particle size reduction, emulsification, and dispersion of materials. It is widely used in biotechnology, pharmaceuticals, chemicals, and food processing. The core mechanism involves forcing materials through a narrow homogenizing valve or diamond interaction chamber under extreme pressure, leveraging cavitation, shear forces, and impact effects for particle breakdown.
1. Core Structure & Working Principle
Power System:
Hydraulic-driven or PLC-controlled, with precise pressure adjustment.
Some lab models feature manual lever pressurization.
Homogenizing Unit:
Diamond Interaction Chamber: Highly wear-resistant, enabling nanoscale particle control (e.g., liposomes, nanoemulsions).
Adjustable Homogenizing Valve: Controls pressure via slit size for optimized fragmentation.
2. Key Applications
Biotechnology: Cell disruption (E. coli, yeast, etc.).
Pharmaceuticals: Preparation of emulsions, suspensions, and controlled drug particle distribution.
Nanomaterials: Dispersion of graphene, conductive pastes, etc.
Food/Cosmetics: Production of nano-functional beverages and skincare products.
3. Technical Advantages
Modular Design: Compact structure for quick assembly.
Temperature Control: Water-cooling system maintains sample stability.
High Throughput: Some models reach 300 L/h processing capacity.
4. Operational Workflow Example
Sample Injection: Load material into the high-pressure cylinder (check valve prevents backflow).
Parameter Setting: Adjust pressure via touchscreen or manual control.
Processing & Cooling: Ultra-high-pressure treatment followed by cooling collection.
Disperser Description
High-Pressure Homogenizer Technical Overview
A high-pressure homogenizer (HPH) is an industrial device that utilizes ultra-high pressure (up to 2,000+ bar) to achieve nanoscale particle size reduction, emulsification, and dispersion of materials. It is widely used in biotechnology, pharmaceuticals, chemicals, and food processing. The core mechanism involves forcing materials through a narrow homogenizing valve or diamond interaction chamber under extreme pressure, leveraging cavitation, shear forces, and impact effects for particle breakdown.
1. Core Structure & Working Principle
Power System:
Hydraulic-driven or PLC-controlled, with precise pressure adjustment.
Some lab models feature manual lever pressurization.
Homogenizing Unit:
Diamond Interaction Chamber: Highly wear-resistant, enabling nanoscale particle control (e.g., liposomes, nanoemulsions).
Adjustable Homogenizing Valve: Controls pressure via slit size for optimized fragmentation.
2. Key Applications
Biotechnology: Cell disruption (E. coli, yeast, etc.).
Pharmaceuticals: Preparation of emulsions, suspensions, and controlled drug particle distribution.
Nanomaterials: Dispersion of graphene, conductive pastes, etc.
Food/Cosmetics: Production of nano-functional beverages and skincare products.
3. Technical Advantages
Modular Design: Compact structure for quick assembly.
Temperature Control: Water-cooling system maintains sample stability.
High Throughput: Some models reach 300 L/h processing capacity.
4. Operational Workflow Example
Sample Injection: Load material into the high-pressure cylinder (check valve prevents backflow).
Parameter Setting: Adjust pressure via touchscreen or manual control.
Processing & Cooling: Ultra-high-pressure treatment followed by cooling collection.