Photovoltaic Industry - Indium Recouped
Challenge
The separation of indium from the other metals and recouping indium in a metallic form without the use of electrochemical purification or a vacuum furnace to melt the metal powder into the metallic indium.
Deposition
Copper, Indium, Gallium, and Selenium
Substrate
Aluminum, Stainless Steel
Results
As far as we know, this is the only existing technology that recoups indium while bypassing electrochemistry and smelting.
One of our clients, involved in the cleaning of precision parts, asked us to demonstrate the ability to etch photovoltaic depositions of copper, indium, gallium (CIG) or copper, indium, gallium, selenium (CIGS) from aluminum and/or stainless steel precision parts and recycling indium out of the mix of the three or four metals.
Several of our clients, that are involved in cleaning precision parts, asked us to come up with a concept of etching photovoltaic deposition of silicon nitrides from stainless steel and/or carbon fiber carriers (CFC) and/or graphite precision parts, without the use of hydrofluoric acid.
Since hydrofluoric acid (HF) is a gas dissolved in water, its fumes always stay in pores of CFCs and/or graphite, which can produce outgassing of the components in the vacuum chamber prior to the coating step. This increases the time to optimum vacuum to start the pretreatment and coating process for both PVD and CVD systems.
It is also very aggressive and destroys stainless steel fasteners (bolts, screws, washers, nuts, rivets, etc.) on the CFC frames so they need to be replaced right after the deposition is etched away.
We were given the task to develop a technology that would avoid using hydrofluoric acid and after some trial experiments we came up with two novel technologies.
We assisted in scaling up the less expensive one. This technology saves production time while increasing the productivity during the production of photovoltaic films significantly. Since the etching mix is not as aggressive as the mix with hydrofluoric acid (HF), the precision parts cleaned by this technology last between ten to fifteen times longer than those with cleaned by the previous cleaning HF cleaning method.
The extraction of chromium from stainless steel treated by hydrofluoric acid (HF) was measured and we found that the amount of chromium extracted by hydrofluoric acid is ten times higher than for the stainless steel precision part that had been treated by our non-HF technology.
All the customers switched from the HF technology to our non-HF novel technology right after their trial tests.