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Additional Capabilities: | Milling |
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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 |
Tip Head Material |
Titanium Alloy |
Titanium Alloy |
Titanium Alloy |
Titanium Alloy |
Power ultrasound is well known for its intense and precisely controllable milling and dispersing effects. Industrial ultrasonicators provide a highly uniform particle size distribution in the micron- and nano-range. Industrial ultrasonicators process easily large volume streams of high viscosities and fulfil a homogeneous wetting, dispersing, deagglomeration and milling.
Paint Manufacturing with Ultrasound
Formulation: Whether high viscosities, high particle loads, aqueous- or solvent-based - with Hielscher's industrial inline ultrasonicators you can process any formulation. Micron- and Nano-Size: The cavitational high shear forces reduce particles to minute particle diameters and provide an uniform dispersion. Optical Properties: To obtain the correct optical properties, pigment particle size have to be controlled. Usually, opacity correlates with particle size: the finer the particle size, the more opacity. For example, TiO2 is specifically processed to a particle size of 0.20 to 0.3 micron, which is approximately the equivalent to one-half the wavelength of light. Ultrasonication reduces the TiO2 pigments to their optimum size, so that ultimate hiding is obtained. High-Performance Particles: Smaller particle sizes result in greater colour saturation, colour consistency and stability. The intense, yet precisely controllable ultrasound forces allow for producing modified and functionalized nano-particles, such as coated particles, SWNTs, MWCNTs and core-shell particles. Such particles show unique characteristics and elevate paint or coating formulations to a new level of quality and functionality (e.g. UV resistance, scratch resistance, strength, adhesiveness, high heat resistance, infrared and solar reflectivity). Modified Particles: Surface modified pigments have very low viscosity at high pigment loadings (2.5cP at 10% solids), superior suspension stability and high purity
Use ultrasonics for the production of final formulations master batches of pigment paste refining particles after conventional milling Ultrasonic Paint Processing Ultrasonic Processing: 7x UIP1000hdT Information Request Name Email address (required) Product or area of interest Note our privacy policy. Request information For the production of paint, the components such as pigments, binders/ film formers, diluents/ solvents, resins, fillers and additives have to mixed together into a homogeneous formulation. Pigments are the determining component that gives paint its color. The most important white pigment is TiO2, which needs to be milled to a optimum particle size between 0.2 and 0.3 microns in diameter to show the desired grade of whiteness, brightness, opacity and a very high refractive index. The ultrasonic shear forces provide a very effective and energy-effective deagglomeration and dispersion of TiO2 particles (see chart below). Ultrasonic milling and dispersing influences the quality of paint improving its color strength, density, fineness of grinding, dispersion and rheology.
Dispersion of Nanoparticles
Ultrasonic grinding and dispersing is often the only method to process nano particles efficiently in order to obtain primary particles. A small primary particle size results in a large surface area and correlates with the expression of unique particle characteristics and functionalities. At the same time, a smaller particle size is associated with a high surface energy for more severe aggregation and reactivity, so that the intense ultrasonic dispersing forces are required to disperse the nano particles homogeneously into the formulation. Furthermore, an ultrasonic surface treatment can modify the nano particles which leads to improved dispersability, dispersion stability, hydrophobicity and other features. Researchers have recommended the ultrasonic dispersion method for nano particles as preferred solution, "because the material dispersed by the ultrasonic method is much purer than that produced by bead milling.