Silicon Carbide (SiC) granules are strong and resilient materials ideal for use in abrasive applications. Furthermore, their inert nature makes them suitable for electronics that operate at higher temperatures and frequencies.
SiC is currently produced through an Acheson process that involves reacting quartz sand and petroleum coke in massive open-air furnaces.
Cost
Humans have exploited Earth’s natural resources for all manner of uses, from growing food to producing electricity. But our consumption can have both economic and environmental repercussions; some materials are scarce while the prices can quickly skyrocket. To preserve access to such vital resources for future generations, recycling should become part of everyday practice; many metal cutting industry manufacturers are already taking steps toward recycling used carbide cutting tools in order to both cut costs while helping the environment.
Production of silicon carbide can be an energy-intensive industrial process that produces large volumes of waste and byproducts. Fraunhofer IKTS researchers have developed an environmentally-friendly process that recycles this byproduct material back into high-grade silicon carbide for reuse while simultaneously reducing industrial pollution levels and saving energy.
This method utilizes stirring, anti-sedimentation and screening to extract high purity SiC micron powder without further treatment for reuse without increasing carbon emissions by up to 75% compared with current Acheson process production methods.
Before recently, most waste resulting from Acheson processes was either used for production of inferior reaction- or nitride-bonded silicon ceramics or left as residue; however, demand for these products was low, while disposal costs for residue sludges can be expensive; additionally, such residues contain contaminants that cause corrosion problems in metal cutting industries.
Fraunhofer IKTS’ team has developed an efficient system to address this problem by recycling powdery waste products into high-grade silicon carbide. Additionally, this approach can also be applied to waste from other production-related activities, such as abrasive slurries.
The system utilizes a foam flotation process to separate silicon from byproducts, with foam being separated out using an emulsifier before being heated to form solid silicon carbide crystals. Molten silicon then goes through vacuum and gas refining processes in order to produce metallurgical grade silicon that is then fed directly into a vertical Bridgeman furnace for crystal formation.
Environmental Impact
Silicon carbide (SiC) is an extremely durable industrial material renowned for its extreme hardness and heat resistance, making it highly useful in technical ceramics and refractories. However, traditional production methods for SiC production require substantial energy expenditure and release considerable carbon dioxide emissions into the atmosphere. Rice waste emissions pose a great danger, particularly to high-tech industries reliant on it for raw material production. A newly patented recycling technology may help mitigate their impact by using rice waste as raw material instead of emitting it as waste material. This technology employs the Flash Joule Heating Process, in which a current is passed through moderately resistant material to quickly heat it and transform into other materials. This can reduce industrial pollution as well as supply constraints of fresh raw material sources.
Recycling SCW involves an intricate series of steps that should be conducted by either an expert or a specialized company. Once recycled slurries have been combined with other raw materials to form composite materials for use in manufacturing processes, not only is the final result cost-effective but it helps minimize environmental impacts of raw silicon while simultaneously decreasing landfill space needs and toxic chemical emissions into the atmosphere.
Conventional methods of separating solid SiC from liquid silicon involve foam flotation and acid leaching, which require excessive energy inputs as well as large volumes of organic solvents that may harm animals, ecology and cause accidents during processing; they may even pose health hazards to workers involved with production. Therefore, an alternative means for extracting silicon from solid silicon carbide must be found.
Rice University researchers have devised an efficient upcycling process that transforms glass fiber-reinforced plastic (GFRP) into silicon carbide for aerospace applications and sandpaper production. Flash Joule heating – where an electric current passes quickly through material to quickly heat it to very high temperatures – allows this transformation. Resulting chemical reactions then cause transformations into various substances; helping aerospace industries reach sustainability goals more easily while decreasing raw material requirements.
Bezpečnosť
Production of silicon carbide requires significant energy inputs and generates an enormous amount of waste material, but thanks to research at Fraunhofer Institute of Ceramic Technologies and Systems IKTS in Dresden, Germany, waste can now be transformed into high-grade silicon carbide products with reduced industrial pollution levels, costs and greenhouse gas emissions. This breakthrough technology has revolutionized production.
Flash Joule heating technology relies on passing an electrical current through moderately resistive materials at moderately high resistance to rapidly heat them to very high temperatures, creating silicon carbide which can then be transformed into other substances for use across a range of products from semiconductors to sandpaper – offering potential solutions to the disposal of glass fiber-reinforced plastic (GFRP), which typically ends up buried in landfills once its useful life has ended. This solution could provide a potential solution to glass fiber-reinforced plastic (GFRP), which tends to end up in landfills upon reaching its useful life span – helping solve an otherwise costly waste problem with its final disposal by recycling its constituent parts instead.
Recent publication in Nature Sustainability highlighted a new method for recycling silicon carbide using flash Joule heating power generation to transform GFRP waste into high-grade silicon carbide at reduced costs and with significantly fewer pollutants produced than incineration or solvolysis processes.
This method is based on the principle that silicon and silicon carbide can be separated using electric repulsion, particle size and density to separate. Furthermore, this approach does not require expensive equipments or organic solvents and can even be completed using liquid substrate without needing to agitate the mixture; furthermore it has proven more efficient than using traditional methods with an aqueous solution solution.
After isolating solid silicon from silicon carbide, it is then immersed in acid solutions such as hydrochloric, nitric, or sulfuric acids or their combinations to produce purified silicon powder. Once this step has been completed, any excess acid solution must be exhausted off in order to obtain pure silicon powder as the end product.
RECOSiC can recycle up to 75% of primary raw materials used to manufacture SiC, producing high-purity green SiC with various polytypes. It can be used in an array of applications and is significantly safer than existing industrial processes which produce toxic SOx, NOx and heavy metal emissions. In addition, using recycled waste material and renewable natural gas (biogas), making production cost effective and environmental friendly.
Recyclability
Silicon carbide’s economic viability depends on its recyclability. Recycling capabilities vary depending on its morphology and structure, which can be modified via thermal treatment or other methods. One cost-effective method to recycle silicon is through using recycled wafers discarded during production as an economical source of silicon carbide recycling for multiple uses such as making ceramics and ballistic protective materials – cutting energy consumption by up to 80% while significantly lowering CO2 emissions in this process.
As part of efforts to increase recyclability of silicon carbide, new manufacturing technologies are being created. These processes aim at both improving quality of silicon production and increasing recycling rates, such as through the reprocessing of PV waste solar panels that can produce high-purity metallurgical silicon or wafer cutting sludge recycling via carbothermal reaction; both methods can significantly lower energy consumption while cutting CO2 emissions by an estimated 80-90% and 33%, respectively.
Silicon carbide is an integral material in the electronics industry and its production often consumes significant amounts of energy while producing significant waste, necessitating measures to lower both costs. Therefore, finding ways to cut these energy and waste costs should be prioritized.
Silicon carbide recycling uses a two-stage heat treatment process: first heating raw material to 2,400degC; then applying thermal radiation treatment which forms SiC crystals that can then be recycled for production of high-quality products. Unlike Acheson method, this recycling method is more cost-effective and poses less environmental hazards.
Sludge generated during silicon carbide production includes a mixture of silicon, ethylene glycol, cooling water and impurities that is valuable for other uses. If not processed properly however, this sludge may contain iron particles and other impurities harmful to human health that should be dewatered and filtered out before reuse for other purposes. An acid solution should also be soaked into silicon powders to wash and remove impurities that remain. An electromagnet can be used magnetically separate any impurities covered by silicon powders.