- Net Power Output:100W
- Power Supply:85-260V/50-60Hz
- Temperature Setting:0-300 ℃, 1℃progressive
- Power Regulation:1%-100%, 1% progressive
Ultrasonic Cell Disruptor, USCG-100
1. Working Principle
First, the supply electric power is converted into high frequency and high voltage power. This energy is transferred to the transducer and converted into high-frequency mechanical vibration, which is then amplified by amplitude displacement and then the energy is aggregated by the titanium alloy probe. When this energy is applied on the liquid, it will generate a powerful pressure wave. This pressure wave will form millions of microscopic bubbles, which will grow rapidly with high frequency vibration and then suddenly close. When the bubbles are closed, a strong shock wave is generated due to collision between the liquids, and the pressure is equal to thousands of atmospheric pressures (ie, ultrasonic cavitation). It causes strong shearing motion on the top of the titanium alloy probe and shears the molecules in gas into smaller fragment. Ultrasonic cavitation is a unique physical process when strong ultrasound is emitted in liquid. It is accompanied by many effects, mainly as follows: high temperature effect, discharge effect , luminescence effect and jet, impact, pressure effect, etc. This energy is sufficient to crush cells, degrade, reorganize and homogenize various inorganic substances or pulverize nanomaterials.
2. Product Features
■ Automatic resonance point, 24KHz (19-26KHz Automatic Frequency Scanning and Checking);
■ Automatic amplitude compensation, which can automatically work at the optimal frequency point and output point according to the fluidity of the sample;
■ Adopting color touch screen controller, all functions are displayed integrated;
■ Scientific design, 10 groups of users store settings and can be directly implemented on a single machine;
■ Independent on/off pulse with 3 modes of continuous use, pulse and timed continuous use.
■ 2D and 3D ultrasound probe design, which greatly improves efficiency and reduces the loss of the horn compared to conventional ultrasound;
■ The device is equipped with a temperature sensor for temperature-sensitive sample;
■ Automatic overload protection, over temperature and fault alarm.
■ Small bulb inside the box allows to observe the status of the sample during processing.
|Net Power Output||100W|
|Nominal Frequency||24KHz, real-time display (19-26KHzAutomatic Frequency Scanning and Checking)|
|Timer||1 min~99H can be set|
|Power Regulation||1%-100%, 1% progressive|
|Temperature Setting||0-300 ℃, 1℃progressive|
|Store Data||10 Groups (Set, Store, Check in Work Status)|
|Pulser||Closed, open, 1S-60min can be set|
|LCD Display Screen||Color Touch Screen, Resolution: 400 x 240|
|Main Interface Display Parameters||Ultrasound Output Power, Frequency, Working Mode, User Group, Setting Key, Operation Status, Start/Stop, Operation Parameters|
|Running Interface SDisplays||Total running time, working time, pause time, user group, overload temperature, power output ratio, working mode, program save key|
|Small Bulb||Small bulb inside the box allows to observe the status of the sample during processing.|
|Configuration of Piezoelectric Frequency Converter|
|Piezoelectric Frequency Converter||CV33, PZT Lead Zirconate Titanate Piezoelectric Ceramics|
|Standard Amplifier||Aluminum Alloy Material: T1-6AL-4V|
|Total Length||105-115mm (variable ratio)|