Of course. Here is a 500-word description of the price factors for a Periodic Vacuum Induction Casting Furnace (receiving tank type).The price of a Periodic Vacuum Induction Casting Furnace, specifically the receiving tank type, is not a single figure but a significant capital investment determined by a complex interplay of its advanced technical specifications, construction quality, and performance capabilities. This specialized equipment, designed for high-precision melting and casting of reactive and high-purity metals like titanium, nickel-based superalloys, and advanced intermetallics, commands a premium price due to its sophisticated engineering.The core cost driver is the furnace's capacity and power rating. Prices escalate substantially with increases in melt capacity (e.g., from a 10 kg charge to a 200 kg charge) and the required power of the induction system to achieve the necessary superheat and pouring temperature. A larger, more powerful furnace requires a heavier-duty power supply, larger vacuum system, and more robust mechanical components, directly impacting the cost.The vacuum system itself is a major cost component. The level of vacuum required, often reaching high vacuum (10⁻⁵ to 10⁻⁶ mbar) or even ultra-high vacuum, dictates the choice and combination of pumps—such as robust roots-mechanical pump systems coupled with diffusion or turbomolecular pumps. The quality, pumping speed, and ultimate vacuum of this system are critical for melt purity and are reflected in the price.The materials used in construction are paramount. The furnace chamber, crucible, and particularly the receiving tank mold assembly must be constructed from high-integrity materials like double-walled stainless steel with advanced cooling channels. Internal components require high-temperature alloys and refractory metals that can withstand extreme thermal cycling and prevent contamination. The use of specialized, high-purity graphite or water-cooled copper crucibles adds further cost.The level of automation and control is another significant factor. A basic manual system is less expensive than one with a fully automated, programmable logic controller (PLC) and human-machine interface (HMI). Advanced features like automated pour control, data logging, recipe management, and real-time monitoring of critical parameters (vacuum, temperature, power) enhance reproducibility and safety but increase the initial investment.Finally, ancillary requirements and compliance contribute to the total cost. This includes the integrated cooling water system, necessary safety interlocks, installation, commissioning, and training. Furthermore, adherence to international safety and quality standards adds to the engineering and manufacturing overhead.In conclusion, the price for a receiving tank-type furnace can range from several hundred thousand to well over a million dollars. The final cost is a direct function of the desired performance, size, material compatibility, and level of automation, making each system highly customized to the end-user's specific research or production needs.