Cryogenic deflashing
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Cryogenic deflashing is a deflashing process that uses cryogenic temperatures to aid in the removal of flash on cast or molded workpieces. These temperatures cause the flash to become stiff or brittle and breaks away cleanly.
Process
Parts are loaded into a parts basket. Using a cryogen such as liquid nitrogen (which can reach the glass transition point of a wider array of materials when compared to dry ice (-109F)), the temperature of the chamber (and the parts) is lowered to a programmable point. The parts are tumbled and blasted with media pellets that are sized between 0.006” and 0.080”. The parameters vary widely based on machine manufacturer.
In some instances, cryogenic deflashing does not utilize a blasting action, relying instead only on the tumbling of the parts to remove flash on the outer edges. This early technique, still in use today, was widely employed in the rubber molding industry for automotive components.
Advantages and disadvantages
Cryogenic deflashing provides various advantages over manual deflashing and other traditional deflashing methods.
- The process maintains part integrity and critical tolerances.
- Since it is a batch process, the price per piece is far less as many more parts can be processed in a given amount of time.
- Cryogenic deflashing extends mold life. Rather than replace or repair a mold (which typically involves downtime and high cost), the parts can be deflashed. This is typical of parts molded at the end of their product lifetime.
- The process is computer controlled, therefore removing the human operator variable from the process.
- The process offers consistent results lot to lot.
- Cryogenic deflashing is non-abrasive.
- Cost per part is generally well below any alternative technique.[citation needed]
Applications
A wide range of molded materials can utilize cryogenic deflashing with proven results. These include:
- Silicones
- Plastics – (both thermoset & thermoplastic)
- Rubbers – (including Neoprene & Urethane)
- Liquid crystal polymer (LCP)
- Glass-filled nylons
- Aluminum zinc die cast
Typical examples of applications that use cryogenic deflashing include:
- O-rings & gaskets
- Catheters and other in-vitro medical
- Insulators and other electric / electronic
- Valve stems, washers and fittings
- Tubes and flexible boots
- Face masks & goggles
Today, many molding operations are using cryogenic deflashing instead of rebuilding or repairing molds on products that are approaching their “end-of-life”. It is often more prudent and economical to add a few cents of production cost for a part than invest in a new molding tool that can cost hundreds of thousand of dollars and has a limited service life due to declining production forecasts.
In other cases, cryogenic deflashing has proven to be an enabling technology, permitting the economical manufacture of high quality, high precision parts fabricated with cutting edge materials and compounds.
References
Further reading
- A Cool Technology: Products Finishing Magazine, Matt Little; 4/1/2005 [1]
- An Expert Tells How to Stop Flash, John Bozzelli; 7/2004 [2]