Ultrasonic metal melt treatment system is mainly used in the metallurgical industry. Under ultrasonic vibration conditions, it is beneficial to degas the metal solution, remove impurities, refine grains, and strengthen the leaching process. Conforming to the spirit of "Service First", ALTRASONIC provides lifetime maintenance to its products for as long as they are used by customers.
The ultrasonic sonochemical reaction and synthesis equipment is based on the principle of cavitation, that is, the formation, growth, and implosive collapse of bubbles in a liquid. Cavitational collapse produces intense local heating , high pressures, and enormous heating and cooling rates and liquid jet streams.
Ultrasound creates acoustic cavitation, which produces violently imploding vacuum bubbles, causing shock waves, microjets and strong shear forces as well as extreme local temperatures (~5,000 K)and pressures (~1,000 atm). These extreme conditions result in exceptionally efficient mixing, yielding nanoemulsions with very small droplet sizes and enormous contact areas between all components.
Ultrasonic metal melt treatment system is mainly used in the metallurgical industry. Under ultrasonic vibration conditions, it is beneficial to degas the metal solution, remove impurities, refine grains, and strengthen the leaching process. Conforming to the spirit of "Service First", ALTRASONIC provides lifetime maintenance to its products for as long as they are used by customers.
Ultrasonic metal melt treatment system is mainly used in the metallurgical industry. Under ultrasonic vibration conditions, it is beneficial to degas the metal solution, remove impurities, refine grains, and strengthen the leaching process. Conforming to the spirit of "Service First", ALTRASONIC provides lifetime maintenance to its products for as long as they are used by customers.
Ultrasonic wire harness welding machines are widely used in automobiles, electronic appliances, motors, communication equipment, mechanical equipment, instrumentation and other fields.