By JOSH PALM
In movies, heroes diffuse bombs by blowing them up. In "Die Hard 1," John McClane saves the day by blowing up several stories of Nakatomi Plaza and looked really good doing it. At the National MagLab, our heroes are, fortunately, a little more responsible.
Our resistive magnets need anywhere from 20-30 megawatts of electricity to generate a strong magnetic field. From 2,000 to 4,000 gallons of cold water blast through each magnet to prevent overheating. But to make sure all that water doesn’t conduct electricity, causing the copper coils inside to decay or — worst case scenario — even explode, we depend on a different kind of hero: the resin bed.
What makes our hero so … heroic? We’ll get to that in a minute.
First, let's meet our villains — ions. Tap water is full of them. Ions conduct electrical current, but pure water does not. That’s why we only use pure water too cool our magnets. But by the time it comes out of the magnet, that water is no longer pure. The negatively charged oxygen in the H20 picks up copper ions from the magnet as it rushes through. This water, having been attacked by the ions, is no longer fit to cool our magnets.
Enter our hero, the resin bed: a 600-gallon metal tank, roughly the size of an elephant and filled with tiny resin beads. The ion-filled water is piped into the tank, where it is forcefully sprayed into the resin by an elaborate shower head.
This is where the big fight scene happens. Some of the beads are positively charged (cations) and some are negatively charged (anions). When the water shoots into the resin, the mob of angry cations and anions capture any harmful particles that the water picked up in the magnet and, basically, save the day!
Chalk another victory up to science ...
Thanks to Bryon Dalton, head of magnet operations in the DC Field Facility and scientific advisor on this story. For more information, please visit our tutorial on Deionization or read our story on the cooling and electrical infrastructure for our magnets.