Nanoparticle Dispersion 28KHz 40KHz Ultrasonic Cleaning Machine Digital Sonicator 180W

28KHz or 40KHz Sonicator With 180W Ultrasonic Power For Nanoparticle And Dispersion In Laboratory

Quick detail of Sonicator

1. Easy to use. 

2. It is suitable for using in laboratory for cell disruption,mixing, homogenization and many other applications.

3. Strong power, high efficient and great performance.

4. Competitive reasonable cost.

5. The main material of the sonicator can be stainless steel sus304 or sus316, or titanium alloy, sus304 is weak acid & alkali resistance, sus316 has better performance, and titanium alloy has the best performance and also costs most.  Customer can choose one of them to best meet their needs. servicelife

6. There is teflon coating on the surface of the sonicator which can make the product has better wear resistance performance and servicelife.

Description of Sonicator

The sonication process uses ultrasonic sound waves. During the process, there is a production of thousands of microscopic vacuum bubbles in the solution due to applied pressure. The formed bubbles collapse into the fluid solution during the process of cavitation.

The collapsing of bubbles takes place in the cavitation field leading to the generation of enormous energy as there is a production of waves. This results in the disruption of the molecular interactions between the molecules of water.  As there is a reduction in the molecular interactions, particles start to separate and allow the mixing process to take place.

There is a release of energy from the sound waves that result in friction in the solution. Ice cubes are used during and after the sonication process to prevent the sample from heating up.

Detail Pictures:

Devices employing ultrasonic waves to homogenize samples, particularly cells/subcellular structures in suspension; also includes accessories and support devices such as power options, probes, sound enclosures, and more.

Sonication uses sound waves to disrupt substances. An electrical signal is converted into a vibration that can mix solutions, dissolve solids into liquids, and remove dissolved gas from liquids. When sound waves at ultrasonic frequencies (>20 kHz) are used, the process is called ultrasonification.

In the laboratory, sonication can be applied via an ultrasonic probe, also called a sonicator or sonic dismembrator. The probe creates sound waves that produce pressure, causing liquid streaming and rapid bubble formation. The bubbles are very small at the start, but grow and coalesce, vibrate violently, and then collapse in the process called cavitation.

The shear from the cavitation and the liquid eddying caused by the vibrating transducer (probe) can hasten chemical reactions and break intermolecular bonds. This speeds dissolution and can be used for samples that cannot easily be stirred. Sonication is also used to disrupt or deactivate biological materials. Cells release their contents when cell walls are disturbed (sonoporation) and DNA molecules can be reduced to smaller fragments.

Effective disruption depends on a number of variables, including tip amplitude and intensity; temperature; cell concentration; pressure; and vessel capacity and shape.

Sonication is used in the pharmaceutical, food and pesticide, and cosmetic industries as well as for inks, paints, and coatings, wood and wood treatment, and metal working. Other uses include: breaking up soil aggregates; nanoparticle, nanoemulsion, or nanocrystal production; wastewater purification; de-gassing; extracting seaweed polysaccharides, plant oils, anthocyanins, and antioxidant; biofuel production; de-sulfuring crude oils; and extracting microfossils from rock.