20khz high power ultrasonic mixer for Disperse Nanomaterials
Particle dispersion is an emerging edge subject developed in recent years. The so-called particle dispersion refers to the process of separating and dispersing powder particles in a liquid medium and uniformly distributed throughout the liquid phase. It mainly includes three stages of wetting, de-agglomeration and stabilization of dispersed particles. Wetting refers to the process of slowly adding powder to the vortex formed in the mixing system, so that the air or other impurities adsorbed on the surface of the powder are replaced by liquid. De-agglomeration refers to dispersing aggregates of larger particle size into smaller particles by mechanical or super-growing methods. Stabilization refers to ensuring that the powder particles maintain a long-term uniform dispersion in the liquid. According to the different dispersion methods, it can be divided into physical dispersion and chemical dispersion. Ultrasonic dispersion is one of the physical dispersion methods.
Ultrasonic dispersion method: Ultrasound has the characteristics of short wavelength, approximately straight line propagation, and easy energy concentration. Ultrasound can increase the chemical reaction rate, shorten the reaction time, and increase the selectivity of the reaction; and it can also stimulate chemical reactions that cannot occur without the presence of ultrasound. Ultrasonic dispersion is to directly place the particle suspension to be processed in the super-generation field, and process it with ultrasonic waves of appropriate frequency and power. It is a high-intensity dispersion method. The mechanism of ultrasonic dispersion is generally believed to be related to cavitation. The propagation of ultrasonic waves takes the medium as the carrier, and there is an alternating period of positive and negative pressure during the propagation of ultrasonic waves in the medium. The medium is squeezed and pulled under alternating positive and negative pressures. When ultrasonic waves with a sufficiently large amplitude are applied to the liquid medium to maintain a constant critical molecular distance, the liquid medium will break, forming microbubbles, and the microbubbles will further grow into cavitation bubbles. On the one hand, these bubbles can be re-dissolved in the liquid medium, or they may float up and disappear; or they may break away from the resonance phase of the ultrasonic field and collapse. Practice has proved that there is the most suitable super-generation frequency for the dispersion of suspensions, and its value is determined by the particle size of the suspended particles. For this reason, it is best to stop for a certain period of time after superbirth, and then continue superbirth to avoid overheating. Cooling with air or water during superbirth is also a good method.
Although ultrasonic dispersion is used for the dispersion of ultrafine powder suspensions to obtain an ideal dispersion effect, due to the high energy consumption and the high cost of large-scale use, it is currently used more in laboratories. However, with the continuous development of ultra-surgery technology, It is completely possible for the application of supersonic dispersion in industrial production.
Model |
SONO20-1000 |
SONO20-2000 |
SONO15-3000 |
SONO20-3000 |
Frequency |
20±0.5 KHz |
20±0.5 KHz |
15±0.5 KHz |
20±0.5 KHz |
Power |
1000 W |
2000 W |
3000 W |
3000 W |
Voltage |
220/110V |
220/110V |
220/110V |
220/110V |
Temperature |
300 ºC |
300 ºC |
300 ºC |
300 ºC |
Pressure |
35 MPa |
35 MPa |
35 MPa |
35 MPa |
Intensity of sound |
20 W/cm² |
40 W/cm² |
60 W/cm² |
60 W/cm² |
Max Capacity |
10 L/Min |
15 L/Min |
20 L/Min |
20 L/Min |
Unique password protection, escort your experiment
Touch keyboard, friendly man-machine interface, real-time display of ultrasonic power, running time, real-time temperature.
The ultrasonic power can be adjusted continuously and better experimental conditions can be explored
TFT large screen display, the program can be set to store 20 sets of experimental data, and directly call the experimental conditions, which is convenient and safe.
It has over-temperature, delay, and fault protection, and has independent over-temperature, delay, and fault alarm systems, which protect the test samples to a great extent.
Optional high and low temperature circulating bath, can control the temperature in the material reaction system at -40-200ºC
Optional RS232 communication interface, which can be upgraded to realize data transmission with PC or PLC and other upper computers for remote control.