Difference between revisions of "High Pressure Homogenizers"

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[[Category:Mixing]]{{Knoppen}}
[[Category:Mixing]]{{Knoppen}}
[[File:High Pressure Homogenizers_1.jpg|thumb|200px|right|High Pressure Homogenizer]]
[[File:High Pressure Homogenizers_1.jpg|thumb|200px|right|High Pressure Homogenizer]]
[[File:High Pressure Homogenizers_2.jpg|thumb|200px|right|High Pressure Homogenizers Diagram]]




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==Key Principles==
==Key Principles==
[[File:High Pressure Homogenizers_2.jpg|thumb|200px|right|High Pressure Homogenizers Diagram]]
[[File:High Pressure Homogenizers_Interaction chambers.jpg|thumb|200px|right|Interaction chambers]]
[[File:High Pressure Homogenizers_Interaction chambers_2.jpg|thumb|200px|right|Interaction chambers in homogenization unit]]
The key component of a high pressure homogenizer includes a homogenization unit such as diamond interaction chamber, and a high pressure pump unit. There is a specially designed fixed geometry inside the diamond interaction chamber. Strokes of the piston in the high pressure pump unit drive the samples through the interaction chamber at supersonic speed. In the chamber, materials are subjected to mechanical forces such as high shearing, high-frequency oscillation, cavitation and convective impact, and corresponding thermal effects simultaneously. These mechanical and physiochemical effects can induce change in the physical, chemical, and particle structure of the materials. This results in uniform and smaller nanoparticle size, achieving a homogenization effect.
The key component of a high pressure homogenizer includes a homogenization unit such as diamond interaction chamber, and a high pressure pump unit. There is a specially designed fixed geometry inside the diamond interaction chamber. Strokes of the piston in the high pressure pump unit drive the samples through the interaction chamber at supersonic speed. In the chamber, materials are subjected to mechanical forces such as high shearing, high-frequency oscillation, cavitation and convective impact, and corresponding thermal effects simultaneously. These mechanical and physiochemical effects can induce change in the physical, chemical, and particle structure of the materials. This results in uniform and smaller nanoparticle size, achieving a homogenization effect.
The interaction chamber is the core of the high pressure homogenizer, and its unique geometric internal structure is the main factor determining the effectiveness of the homogenization process. The intensifier pump exerts the required pressure for materials to pass through the interaction chamber at high speed. The pressure’s strength and stability are important to ensure the production of high-quality nanomaterials.  
The interaction chamber is the core of the high pressure homogenizer, and its unique geometric internal structure is the main factor determining the effectiveness of the homogenization process. The intensifier pump exerts the required pressure for materials to pass through the interaction chamber at high speed. The pressure’s strength and stability are important to ensure the production of high-quality nanomaterials.  

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