500L Multi-effect Distilled Water Machine

# 500L Multi-effect Distilled Water Machine Process #

# I. Raw Water Pretreatment The first step in producing high-quality distilled water with a 500L multi-effect distilled water machine is raw water pretreatment. The raw water is typically municipal supply or other sources meeting certain standards. The initial operation involves filtration, using sand filtration and activated carbon filtration to remove large suspended particles, sediment, and to adsorb residual chlorine, organic matter, and some odors. Sand filtration utilizes multiple layers of sand grains of different sizes to trap larger particles; activated carbon adsorbs impurities through its porous structure. Subsequently, softening treatment is carried out, often using ion exchange resins to remove hardness ions such as calcium and magnesium from the water, preventing scale formation during subsequent heating and evaporation processes, which could affect the equipment's heat transfer efficiency and service life. After pretreatment, the quality of the raw water is significantly improved, laying a solid foundation for the subsequent distillation process. #

# II. Heating and Evaporation The pretreated raw water is conveyed to the first-effect evaporator of the multi-effect distilled water machine. In the evaporator, the raw water is heated by steam or other heating media to boiling and evaporation. The multi-effect evaporator utilizes the principle of multiple evaporation and condensation, with each evaporator maintaining specific pressure and temperature conditions. For example, in the first-effect evaporator, the raw water evaporates at higher temperature and pressure, and the generated steam enters the second-effect evaporator as a heating source, enabling the raw water in the second effect to evaporate at a relatively lower temperature, and so on. This multi-effect evaporation method greatly enhances energy utilization efficiency and reduces production costs. Moreover, during evaporation, most impurities in the water remain in the liquid phase due to their higher boiling points, achieving preliminary separation.

 ## III. Separation and Condensation In each evaporator, the generated steam moves upward, while any entrained droplets or impurities are separated through specialized separation devices. These devices include cyclone separators, wire mesh demisters, etc., which utilize principles such as centrifugal force and inertia to remove droplets and fine particles from the steam, ensuring high purity of the steam entering the next-effect evaporator or condenser. The separated steam then enters the condenser, where it condenses into distilled water through heat exchange with cooling water. The design of the condenser is also crucial for the quality of the distilled water, requiring sufficient cooling area and good heat transfer efficiency to ensure rapid and thorough condensation of the steam. #

# IV. Collection and Storage The condensed distilled water is collected in dedicated storage tanks. The 500L production capacity necessitates storage tanks with appropriate capacity and good sealing. During storage, the quality of the distilled water must be monitored in real time, including indicators such as conductivity and microbial content. Simultaneously, the storage tanks require regular cleaning and disinfection to prevent microbial growth and other contamination, ensuring that the final distilled water consistently meets relevant quality standards and satisfies the demand for high-purity distilled water in industries such as pharmaceuticals and electronics.