Difference between revisions of "High Pressure Homogenizers"

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[[File:High_Pressure_Homogenizers_Ceramic_piston.png|thumb|250px|right|Ceramic piston]]
[[File:High_Pressure_Homogenizers_Ceramic_piston.png|thumb|250px|right|Ceramic piston]]
Overall, a cylinder with an intensifier is superior to a direct-drive one.
Overall, a cylinder with an intensifier is superior to a direct-drive one.
Under the same flow rate, higher pressure produces lower frequency, fewer pressure fluctuations, better product quality, and greater equipment durability. At 30,000 psi, a laboratory high pressure homogenizer, can reach fluctuation levels of less than 10 Hz, as opposed to 60 Hz from a normal homogenizer.
Under the same flow rate, higher pressure produces lower frequency, fewer pressure fluctuations, better product quality, and greater equipment durability. At 30,000 psi, a laboratory high pressure homogenizer<ref>NanoGenizer, [https://www.genizer.com/nanogenizer_p0039.html]</ref>, can reach fluctuation levels of less than 10 Hz, as opposed to 60 Hz from a normal homogenizer.
 
High pressure piston materials can be divided into ceramics, tungsten carbide, and hardened stainless steel, with ceramics as the costliest option and hardened stainless steel as the most affordable. Quality and durability align with cost: Ceramic materials offer the highest quality, followed by hard tungsten alloy, with hardened stainless steel as a lower-quality option. 


High pressure piston materials can be divided into ceramics, tungsten carbide, and hardened stainless steel, with ceramics as the costliest option and hardened stainless steel as the most affordable. Quality and durability align with cost: Ceramic materials offer the highest quality, followed by hard tungsten alloy, with hardened stainless steel as a lower-quality option.


==Selecting homogenization parts==
==Selecting homogenization parts==

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