Ultrasonic metal melting homogenizer machine for liquid processor
with lifting stand
Ultrasonic aluminum melt processing equipment utilizes the
propagation and action characteristics of ultrasonic waves in
liquid metal to achieve various treatment effects on molten
aluminum. Specifically, its operating principles include the
following:
Cavitation effect: When ultrasonic waves propagate through molten
aluminum, they generate alternating positive and negative sound
pressures, causing tiny bubbles in the liquid to rapidly collapse
under high pressure, generating localized high temperatures, high
pressures, and microjets. This cavitation effect removes gas and
inclusions from the melt, purifying it.
Acoustic streaming effect: Ultrasonic vibrations induce liquid flow
within the molten aluminum, a process known as acoustic streaming.
Acoustic streaming promotes uniform mixing of the melt, achieving a
more uniform composition within the molten aluminum and reducing
compositional segregation.
Mechanical vibration effect: The high-frequency vibrations of
ultrasonic waves are transmitted to the molten aluminum, generating
mechanical vibrations. This mechanical vibration helps break down
coarse grains and refine them, thereby improving the microstructure
and properties of the aluminum.
Equipment Components: Ultrasonic vibration components include an
ultrasonic transducer, an ultrasonic horn, and a tool head. The
transducer converts the electrical energy input from the generator
into mechanical energy, namely ultrasonic waves. This energy
typically moves back and forth in a longitudinal direction, with an
amplitude of several microns. The horn amplifies the amplitude,
isolates the molten metal from heat transfer, and stabilizes the
entire ultrasonic vibration system. The tool head is connected to
the horn, which transmits the ultrasonic energy vibration to the
tool head, which then transmits the ultrasonic energy into the
molten metal.
The ultrasonic generator: Generates a high-frequency ultrasonic
signal, providing energy for the ultrasonic vibrating components.
Parameters such as output power and ultrasonic frequency can be
controlled to meet different processing requirements.
Equipment Advantages
Improves Product Quality: Significantly refines the grain size,
making the aluminum product's structure more uniform, reducing
defects such as porosity and inclusions, and improving the
aluminum's strength, toughness, and ductility, thereby enhancing
the overall performance of the product.
Optimizes Production Process: Simultaneously achieves multiple
functions, including degassing, refining, and homogenization,
streamlining the process, shortening production time, and improving
production efficiency. Reduced Production Costs: Replaces
traditional Al-Ti-B refiners, reducing slag volume by 30%-50%,
while also reducing fuel, electricity, and other energy
consumption, as well as labor and equipment maintenance costs.
Environmentally Friendly: No toxic emissions, making it more
environmentally friendly.
Easy Installation: Connects to existing production lines via
standard flanges, eliminating the need to modify existing
production equipment or processes, making it easy to retrofit and
apply to existing production lines.
Applications:
Aluminum Alloy Casting: Produces high-quality ingots, reduces
casting defects such as porosity and shrinkage, improves the yield
rate of castings, and improves the surface quality of ingots,
resulting in a smoother surface. It is highly effective for casting
billets, blooms, and slabs.
Aluminum Extrusion: The treated aluminum melt improves the surface
quality and dimensional accuracy of extruded products, ensuring
that the extruded aluminum meets high-precision requirements.
Automotive Lightweighting: Provides strong support for the
production of high-performance aluminum alloy parts, helping to
improve vehicle fuel efficiency and safety, and meeting the
automotive industry's demand for lightweight, high-performance
materials. Aerospace: It helps to manufacture high-strength and
high-reliability aluminum alloy structural parts, meeting the
strict requirements of the aerospace field on material quality and
performance.
Parameter:
| Item | sono-20-1000 | sono-20-2000 | sono-20-3000 | sono-15-3000 |
| Frequency | 20khz±0.5 | 20khz±0.5 | 20khz±0.5 | 15khz±0.5 |
| Power | 1000w | 2000w | 3000w | 3000w |
| Voltage | 110 or 220V |
| Max temp | 300℃ |
| Max pressure | 35Mpa |
| Itensity of sound | 20W/cm² | 40W/cm² | 60W/cm² | 60W/cm² |
| Capacity | 10L/min | 15L/min | 20L/min | 20L/min |
| Material of probe | Titanium |
When selecting the appropriate ultrasonic equipment for treating
molten aluminum, you need to comprehensively consider technical
parameters such as power, frequency, and processing capacity. You
should also consider factors such as equipment quality and ease of
use. The following are key points:
Power Selection: Higher power generally results in higher
processing efficiency, but also greater energy consumption and
correspondingly higher costs. This power requirement is determined
based on production scale and processing requirements. Generally,
small laboratory equipment may have a power of 1000W-3000W, while
large-scale industrial production equipment can reach several
kilowatts or even higher.
Frequency Selection: Ultrasonic frequencies typically range from
20kHz to 100kHz. Low-frequency ultrasound has stronger energy and a
more pronounced cavitation effect, making it more effective in
removing impurities and gases and breaking up grains.
High-frequency ultrasound can more precisely target tiny particles
in the melt, resulting in better refinement. When treating molten
aluminum, a common frequency is around 20kHz. The frequency can be
selected based on specific process requirements.
Processing Capacity Matching: Select equipment with the appropriate
processing capacity based on the single batch volume of molten
aluminum to be processed during production. If the processing
volume is small but the equipment capacity is large, energy waste
and costs will increase. Excessive processing volume that exceeds
the equipment's capacity will not achieve the desired processing
results. Refer to the equipment manual for parameters such as the
appropriate crucible size and melt volume to determine appropriate
processing results.
Equipment Material Considerations: Due to the high temperature of
the molten aluminum, the equipment parts that come into contact
with the melt must possess excellent heat and corrosion resistance.
Tool heads are generally made of high-strength titanium alloy,
capable of withstanding temperatures around 800°C and exhibiting
strong corrosion resistance, ensuring long-term, stable operation.
Equipment Quality and Stability: Choose a well-known brand and a
reputable manufacturer. Their equipment offers greater assurance of
manufacturing processes and component quality, resulting in higher
stability and reliability. Learn about the equipment's service life
and failure rate, and consult with other users about their
experiences.
