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RPS-SONO20
RPS-SONIC
Place of Origin | China |
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Brand Name | RPS-SONIC |
Certification | CE |
Model Number | RPS-S20-2000 |
Minimum Order Quantity | 1set |
Price | negotiation |
Packaging Details | Foam And Wood Box |
Delivery Time | 3days |
Payment Terms | T/T, Western Union, MoneyGram |
Supply Ability | 200 sets per month |
Parameter
Item | Frequence | Max power | Handing capacity | Material |
RPS20-S2000 | 20K±1KHz | 2000W | ≤ 300 L/h | Titanium Sonotrode |
RPS28-S200 | 28K±1KHz | 200W | ≤ 200 L/h | |
RPS28-S400 | 28K±1KHz | 400W | ≤ 300 L/h | |
RPS28-S500 | 28K±1KHz | 500W | ≤ 300 L/h | |
RPS28-S600 | 28K±1KHz | 600W | ≤ 400 L/h | |
RPS28-S800 | 28K±1KHz | 800W | ≤ 500 L/h | |
RPS30-S100 | 30K±1KHz | 100W | ≤ 200 L/h | |
RPS30-S200 | 30K±1KHz | 200W | ≤ 200 L/h | |
RPS30-S250 | 30K±1KHz | 250W | ≤ 200 L/h | |
RPS30-S400 | 30K±1KHz | 400W | ≤ 300 L/h | |
RPS30-S500 | 30K±1KHz | 500W | ≤ 300 L/h | |
RPS35-S150 | 35K±1KHz | 150W | ≤ 200 L/h | |
RPS40-S100 | 40K±1KHz | 100W | ≤ 200 L/h | |
RPS40-S50 | 40K±1KHz | 50W | ≤ 100 L/h |
Description
Ultrasonic nanomaterial dispersion is the process of using ultrasonic technology to evenly disperse nanoparticles or nanomaterials in a solution or matrix. Ultrasonic waves can break up aggregated nanoparticles through cavitation effect and shear force, dispersing them into independent small particles and avoiding agglomeration or precipitation between nanoparticles, thereby obtaining a more uniform and stable nanomaterial dispersion system. This technology is widely used in the preparation of nanomaterials, preparation of nanomedicines, surface treatment, coatings, catalysts, and energy storage materials.
Working principle
1. Cavitation effect: Ultrasonic transducers convert electrical energy into high-frequency mechanical vibrations (usually 20 kHz to 100 kHz), which are transmitted through liquids. In liquids, the pressure waves generated by ultrasound cause tiny bubbles in the liquid to expand and collapse periodically, a phenomenon called cavitation effect. The local high temperature and high pressure generated when the bubbles collapse, as well as the instantaneous liquid flow impact, can produce strong shear forces on the particles, destroying the agglomeration between particles, thereby dispersing the particles into smaller particles or single particles.
2. Shear force and shock wave: The shear force generated by ultrasonic vibration destroys the adhesion and aggregation forces between particles, especially when the particles are large or tightly aggregated, ultrasound can effectively disperse the particles. Especially in high-concentration nanoparticle solutions, ultrasound can decompose nanoparticles from aggregated states into independent, evenly distributed small particles through effective shear force and shock waves.
3. Particle fragmentation and dispersion: Ultrasonic waves break up larger nanoparticles or agglomerated particles through the collapse of tiny bubbles and the strong shear force in the liquid, making the particles further refined and evenly dispersed. By adjusting the ultrasonic power, frequency, processing time and other parameters, the dispersion effect and particle size can be controlled.
Types of equipment for ultrasonic dispersion of nanomaterials
1. Desktop ultrasonic equipment: Suitable for dispersing small amounts of samples in the laboratory, easy to operate, and suitable for use in the research and development stage.
2. Industrial-grade ultrasonic equipment: Suitable for dispersing nanomaterials in large-scale production processes. It has a higher power output and can handle larger amounts of liquid and higher concentrations of nanoparticles.
3. Batch and continuous ultrasonic equipment:
Batch equipment: Suitable for processing a certain amount of samples, usually small or medium batches.
Continuous equipment: Suitable for large-scale, continuous production processes, and can continuously disperse nanomaterials.
Parameter
Item | Frequence | Max power | Handing capacity | Material |
RPS20-S2000 | 20K±1KHz | 2000W | ≤ 300 L/h | Titanium Sonotrode |
RPS28-S200 | 28K±1KHz | 200W | ≤ 200 L/h | |
RPS28-S400 | 28K±1KHz | 400W | ≤ 300 L/h | |
RPS28-S500 | 28K±1KHz | 500W | ≤ 300 L/h | |
RPS28-S600 | 28K±1KHz | 600W | ≤ 400 L/h | |
RPS28-S800 | 28K±1KHz | 800W | ≤ 500 L/h | |
RPS30-S100 | 30K±1KHz | 100W | ≤ 200 L/h | |
RPS30-S200 | 30K±1KHz | 200W | ≤ 200 L/h | |
RPS30-S250 | 30K±1KHz | 250W | ≤ 200 L/h | |
RPS30-S400 | 30K±1KHz | 400W | ≤ 300 L/h | |
RPS30-S500 | 30K±1KHz | 500W | ≤ 300 L/h | |
RPS35-S150 | 35K±1KHz | 150W | ≤ 200 L/h | |
RPS40-S100 | 40K±1KHz | 100W | ≤ 200 L/h | |
RPS40-S50 | 40K±1KHz | 50W | ≤ 100 L/h |
Description
Ultrasonic nanomaterial dispersion is the process of using ultrasonic technology to evenly disperse nanoparticles or nanomaterials in a solution or matrix. Ultrasonic waves can break up aggregated nanoparticles through cavitation effect and shear force, dispersing them into independent small particles and avoiding agglomeration or precipitation between nanoparticles, thereby obtaining a more uniform and stable nanomaterial dispersion system. This technology is widely used in the preparation of nanomaterials, preparation of nanomedicines, surface treatment, coatings, catalysts, and energy storage materials.
Working principle
1. Cavitation effect: Ultrasonic transducers convert electrical energy into high-frequency mechanical vibrations (usually 20 kHz to 100 kHz), which are transmitted through liquids. In liquids, the pressure waves generated by ultrasound cause tiny bubbles in the liquid to expand and collapse periodically, a phenomenon called cavitation effect. The local high temperature and high pressure generated when the bubbles collapse, as well as the instantaneous liquid flow impact, can produce strong shear forces on the particles, destroying the agglomeration between particles, thereby dispersing the particles into smaller particles or single particles.
2. Shear force and shock wave: The shear force generated by ultrasonic vibration destroys the adhesion and aggregation forces between particles, especially when the particles are large or tightly aggregated, ultrasound can effectively disperse the particles. Especially in high-concentration nanoparticle solutions, ultrasound can decompose nanoparticles from aggregated states into independent, evenly distributed small particles through effective shear force and shock waves.
3. Particle fragmentation and dispersion: Ultrasonic waves break up larger nanoparticles or agglomerated particles through the collapse of tiny bubbles and the strong shear force in the liquid, making the particles further refined and evenly dispersed. By adjusting the ultrasonic power, frequency, processing time and other parameters, the dispersion effect and particle size can be controlled.
Types of equipment for ultrasonic dispersion of nanomaterials
1. Desktop ultrasonic equipment: Suitable for dispersing small amounts of samples in the laboratory, easy to operate, and suitable for use in the research and development stage.
2. Industrial-grade ultrasonic equipment: Suitable for dispersing nanomaterials in large-scale production processes. It has a higher power output and can handle larger amounts of liquid and higher concentrations of nanoparticles.
3. Batch and continuous ultrasonic equipment:
Batch equipment: Suitable for processing a certain amount of samples, usually small or medium batches.
Continuous equipment: Suitable for large-scale, continuous production processes, and can continuously disperse nanomaterials.
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