Users who choose metal shredders manufactured by reputable factories can reduce their financial investment in this equipment. These metal shredders, produced by specialized manufacturers, are designed specifically for recycling large-scale metal waste. As demand for metal shredding equipment continues to grow in the metal recycling market, sales of these machines from leading manufacturers are steadily increasing.

In the field of environmental protection, precious metal catalysts are widely used in automotive exhaust purification, catalytic combustion of organic compounds, and the oxidation of CO and NO. In the realm of new energy, precious metal catalysts play a crucial role as the core component in the development of next-generation fuel cells.

Secondly, the new materials industry is also a key driver of demand for non-ferrous metals. Emerging materials such as carbon fiber, ceramics, and high-performance polymer composites are increasingly being applied in industries like aerospace, automotive, and energy. Among these, carbon fiber stands out for its exceptional properties—high strength, high modulus, and lightweight characteristics—making it a popular choice in aerospace, automotive, and other sectors. Notably, the production of carbon fiber relies heavily on metallic materials like aluminum, titanium, and chromium. As the new materials industry continues to grow, the demand for non-ferrous metals is expected to rise accordingly.

Keep an eye on the top section of Baijiahao's homepage—consultations about rhodium recycling indicate that rhodium prices have been steadily declining, likely signaling the end of the current easing cycle, as market participants shift to a wait-and-see approach. Meanwhile, with weak demand from key consumer countries, rhodium prices are expected to remain range-bound in the near term. Looking ahead, rhodium recycling is projected to ease next year, helping to safeguard precious metals. Properly managing rusted precious metals not only extends their usable lifespan but also contributes to resource conservation at a deeper level. Importantly, this process involves recovering metals from complex components, effectively mitigating moisture and corrosion that could otherwise trigger harmful chemical reactions. As a result, a protective lubricating film forms on the surface of recovered metal parts, significantly preserving valuable metal resources. Rhodium water recycling, meanwhile, refers to a technique that uses catalysts to passively adsorb or complex metal ions onto surfaces—a method that plays a crucial role in enhancing both efficiency and sustainability in metal recovery processes.

Risks include volatile prices of precious metal raw materials and the high capital-occupation risk, the risk of a shortage in precious metal resources, the risk associated with rapid technological upgrades and iterations in the industry, the risk of slower-than-expected import substitution, the risk that non-precious metal catalysts may achieve breakthrough performance and ultimately replace precious metal catalysts, as well as macroeconomic risks.

Precious metal recycling and the recovery of spent catalysts hold a dominant position in the market: The company’s specially developed incineration-based enrichment equipment, along with its proprietary wet-process recycling technology for recovering and purifying precious metals, ensures that the metal recovery and purification process becomes more efficient, environmentally friendly, and sustainable—providing robust support for the long-term growth of the company’s precious metal recycling business.

Rhodium recovery and purification primarily involve two methods: wet processing and incineration. Currently, in modern industrial practices, the incineration method is widely used for treating various precious metal wastes. Take waste rhodium-carbon catalysts as an example: First, the spent rhodium catalyst undergoes high-temperature calcination to remove any remaining organic materials still attached to the rhodium waste. After this oxygen-assisted, high-temperature calcination process, the organic components are completely eliminated, yielding a rhodium-rich ash. Next, a treatment agent is added to the rhodium ash for pre-processing, followed by the introduction of a solvent to dissolve the rhodium residue. Once dissolution is complete, the mixture is filtered to produce a crude rhodium solution. This crude solution is then purified further using ion-exchange techniques to eliminate other metallic impurities. Finally, a reducing agent is added to precipitate pure rhodium powder, which is subsequently refined through smelting to yield high-purity rhodium metal.