A schlieren image of the shock wave plastic/metal separation induced by the pulsed electric discharge at 4.35 μs. Fragments of the plastic and metal layers (white circles) are clearly seen being blown away from the tips of the electrodes where the electric discharge has occurred. Cedit:Hamid Hosano
E-waste recycling is far below what it should be to reduce its impact on the environment and human health simply because it is not economically feasible. Researchers from Japan are working on a way to change that using pulsed power technology.
As the number of electronics devices increases around the world, finding effective methods of recycling electronic waste (e-waste) is a growing concern. About 50 million tons of e-waste is generated each year and only 20% of that is recycled. Most of the remaining 80% ends up in a landfill where it can become an environmental problem. Currently, e-waste recycling involves mechanical crushers and chemical baths, which are expensive, and manual labor, which can cause significant health and environmental problems when not performed properly. Thus, researchers from Kumamoto University, Japan have been using pulsed power (pulsed electric discharges) to develop a cleaner and more efficient recycling method.
Pulsed power has been shown to be successful in processing various waste materials, from concrete to waste water. To test its ability to be used in e-waste recycling, researchers examined its effectiveness in separating components found in one of the most prolific types of e-waste, CD ROMs. In previous work, they showed that complete separation of metal from plastic occurred using 30 pulses at about 35 J/pulse (At the current price of electricity in Tokyo, this amount of energy costs about 0.4 Yen for recycling 100 CD ROMs). To examine the mechanism of material separation using this method, researchers performed further analyses by observing the plasma discharge with a high-speed camera, by taking schlieren visualizations to assess the shock wave, and using shadowgraph images to measure fragment motion.
Images at the early stage of electrical discharge showed two distinct light emissions: blue-white and orange. These indicated excitation of aluminum and upper protective plastic materials respectively. After the plasma dissipated, fragments of metal and plastic could be seen flying away from the CD ROM sample.
Schlieren images were taken throughout the process and revealed that the main destructive shock waves developed around the two electrodes. The shock produced a pressure of over 3.5 MPa (about the same amount of pressure a galloping horse will exert on the ground) near the tips of the electrodes and quickly fell to below 0.8 MPa at 7.1 mm. In both the schlieren and shadowgraph images, material dispersal was very clearly observed.
"E-waste is perhaps one of the most important waste recycling problems we face today due to its ubiquitous nature," said study leader Professor Hamid Hosano. "Our project showed the importance of shock waves when using pulse power for material removal and separation in e-waste recycling. We believe our data will be important in the development of future recycling projects."