|Material:||Stainless Steel 304 / 316||Application:||Remove Plastic, Resin, Hard Wax|
|Option:||Oil Filteration||Industry:||3D Printed Ultrasonic Cleaner|
digital ultrasonic cleaning machine,
ultrasonic digital cleaner,
3D Printed Parts Ultrasonic Cleaner
3D Printed Ultrasonic Cleaner To Cleanup 3D Printed Parts On Plastic, Resin, Hard Wax
Ultrasonic cleaners are available in numerous sizes based on the capacity of the cleaning solution tank, and can range from tabletop models to industrial-sized floor models. Regardless of size they are equipped with ultrasonic generators that excite tank-mounted transducers that create millions of microscopic bubbles in the cleaning solution. These implode on contact with the filters being cleaned to blast away contaminants from any surface wetted by the ultrasonic cleaning solution. Depending on models, ultrasonic filter cleaning equipment such as available have timers, temperature controllers, sweep and degas options. Rinse stations and drying stations are also available for assembly line filter cleaning.
Here’s a simplified series of operation steps for ultrasonic filter cleaning equipment. Modifications can be made based on specific filter cleaning requirements.
1. Add water to the fill line of the ultrasonic cleaning tank and prepare the ultrasonic cleaning solution clean A4 diluted to 2-5% with water. This is formulated for cleaning stainless and carbon steel, copper, brass and plastic.
2. Turn on the ultrasonic cleaner and degas function to both mix and degas the solution. Degassing removes air trapped in the water, which inhibits the cleaning operation. If the cleaner does not have a degas function allow it to run until bubbles stop coming to the surface.
3. Once degassing is complete you’re ready to clean the filters. Set the temperature to about 70°C for metal filters or about 50°C for plastics and the timer to 10 minutes. Experience will tell you the optimum temperature and how much time is required for your particular filter cleaning operations.
4. Place the filters in the cleaning basket so they do not contact each other, lower them into the ultrasonic cleaning solution, turn the unit on and activate the sweep function if so equipped. This evenly distributes the cavitation action throughout the solution for more uniform cleaning.
5. At the end of the cleaning cycle remove and inspect the filters. If they appear clean, rinse and dry. Depending on filter design you can either air blow dry or place them into a drying oven.
6. Apply a filter coating if required. The filters are now ready for reuse.
3D Printers Clener Machines Introduction
Ultrasonic cleaning is a technology that uses high frequency sound waves (ultrasonic: above the range of human hearing) to agitate an aqueous or organic medium (cleaning chemistry) that in turn acts on contaminations adhering to substrates like metals, plastics, glass, rubber and ceramics. Contaminants can be dust, dirty, oil, pigments, grease, polishing compounds, flux agents, fingerprints, soot wax and mold release agents, biological soil like blood, and so on
Ultrasonic cleaning can be used for many applications, including plastic parts, bearing, bolts, rubber parts, internal parts, plastic injection molds, transmission parts, and final cleaning of all engine parts prior to assembly, the versatility of ultrasonic cleaning machine make them the perfect choice for automotive, medical, pharmaceutical, aerospace, engineering and many other industries
Ultrasonics efficiently removes:
varnishes and paints
oil and grease
Why Use 3D Printers Clener Machines Cleaning ?
Anosonics is renowned for their professional cleaning service to the motor industry.
How does ultrasonic 3D Printers Clener Machines cleaning work?
When they become clogged with dirt, grease or other contaminants; ultrasonic cleaners can restore many types of filters to look and function like new. Ultrasonic parts washers are particularly effective for 3D Printers Clener Machines made of metal or plastic mesh; the gentle yet powerful process is much less damaging than traditional cleaning methods that use a brush and high-velocity chemical cleaning solutions. Ultrasonic cleaners use water based solutions that won’t damage filters yet reach every crack and crevice for the best possible clean. Ultrasonic cleaning uses a process called cavitation where microscopic bubbles form from ultrasonic waves, then implode on the part’s components; thereby vigorously yet gently scrubbing and cleaning surfaces and crevices. No matter how stubborn the build-up, your filters will be restored to full working capacity.
|Model||T-36S (Power adjustable, separate generator )|
|Tank size||600x500x450mm (LxWxH)|
|Unit size||740x705x670cm (LxWxH)|
|Packaging size||880x800x770mm (wooden case)|
|Power supply||AC220V, AC 380V, 50/60 Hz, 3phase|
|Tank material||SUS304, 2mm thickness|
|Shell Material||SUS304, 1mm thickness|
|Others||With drainage, basket, lid|
|Warranty||1 year& tech support for life|
AG ultrasonic cleaning machine effectively and thoroughly clean all types of 3D Printers Clener Machines Cleaning
Features of the machine:
• Low maintainence machine
• Heavy duty cleaning systems
• Chemical friendly- SS Rust proof body
• Industrial guage farication, build to last
• One year warrenty on any manufacturing defect
• Completely customized to suit the cleaning requirement
• Less human interfearance and less scope of error
• Accurate and uniform cleaning everytime
Q - Will sonics in a rinse tank w/o soap continue to remove embedded debris?
Absolutely. While detergents aid in the formation of the bubble, cavitation is still very effective in plain water or demineralized water. Where there is cavitation there can still be cleaning.
Q - Are there rules for racking parts- material, coating, or part orientation?
Yes. Never put the parts on the bottom of an ultrasonic tank. You will prevent the correct movement of the diaphragm and interfere with the creation of ultrasonic energy. You can also subject the parts to damage. Parts should be racked in a basket or work holder designed to handle your specific part. This is very important in high end cleaning systems where you want the cleanest part possible. You should always use a stainless steel basket, as softer materials will absorb the ultrasonic energy. Never use plastic or other soft materials. If your part is easily damaged or scratched, stainless steel racks with Nylobond or Teflon coatings are available. Parts should be arranged in a single layer, this gives the cleaning fluid an opportunity to circulate and remove particulate from the immediate area of the part. When removing the parts from the cleaning solution a single layer prevents the upper parts from shedding particles on the lower parts. Never put the parts on the bottom of an ultrasonic tank. This is like putting your thumb on a speaker diaphragm in a radio. You will prevent the correct movement of the diaphragm [bottom or side of the tank] and interfere with the creation of ultrasonic energy.
Contact Person: Jane