Selecting the appropriate coagulant is a critical decision for any water treatment operation, impacting efficacy, cost, and operational complexity. Two of the most widely used inorganic polymer coagulants are Polymeric Ferric Sulfate (PFS) and Poly Aluminum Chloride (PAC). While both serve the primary purpose of removing impurities from water, they possess distinct chemical properties and performance characteristics that make them suitable for different applications. As experienced suppliers of both PFS and PAC, we aim to guide you through this comparison.

Understanding the Basics:

  • Polymeric Ferric Sulfate (PFS): An inorganic polymer coagulant derived from ferric sulfate. It features polynuclear ferric complexes that offer high charge density and excellent flocculation properties. PFS is known for its effectiveness in removing turbidity, color, organic matter, heavy metals, and phosphates, often showing rapid floc formation and sedimentation.
  • Poly Aluminum Chloride (PAC): An inorganic polymer coagulant produced by the polymerization of aluminum chloride. PAC exists in various forms, with differing basicity and molecular weights, influencing its performance. It is highly effective in coagulating a wide range of impurities and is known for its efficiency in cold water and at low turbidity levels.

Key Comparison Points:

  • Contaminant Removal Efficacy:
    • PFS: Excels in removing turbidity, color, heavy metals, and especially phosphates. It is also very effective in decolorizing highly colored industrial wastewater and improving sludge dewatering.
    • PAC: Highly effective for turbidity and organic matter removal. It performs well in cold water and across a broad pH range, often leading to more stable floc formation under varying conditions. Its effectiveness against specific contaminants like phosphates might be less pronounced than PFS in certain scenarios.
  • pH Performance:
    • PFS: Typically operates effectively in a pH range of 4-11, with an optimal range often cited as 6-9. It can cause a slight decrease in pH due to its acidic nature.
    • PAC: Generally effective across a wider pH range, often performing well from neutral to slightly acidic conditions. The impact on final water pH can vary based on the specific PAC product and dosage.
  • Floc Characteristics:
    • PFS: Tends to form dense, compact flocs that settle quickly.
    • PAC: Forms flocs that can be lighter and less dense, though still effective for sedimentation.
  • Sludge Production: Both coagulants generally produce less sludge than traditional inorganic salts. However, the density and settleability of the sludge can differ, impacting dewatering efficiency.
  • Cost-Effectiveness: Both PFS and PAC are generally more cost-effective than older coagulants due to their higher efficiency and lower required dosages. The specific cost comparison can depend on market prices, required dosage for a given water quality, and local logistics.

Which Coagulant is Right for You?

The optimal choice between PFS and PAC often depends on the specific characteristics of the raw water and the primary treatment objectives:

  • For applications requiring exceptional phosphorus removal, strong decolorization, or improved sludge dewatering, PFS is often the preferred choice. Its iron-based chemistry offers distinct advantages in these areas.
  • If the primary challenge is high turbidity, particularly in cold or low-turbidity waters, and maintaining a broad pH operating window is crucial, PAC might be the more suitable option. Its aluminum-based chemistry offers excellent stability and wide applicability.

As a comprehensive supplier, we offer both high-quality Polymeric Ferric Sulfate and Poly Aluminum Chloride. We encourage potential customers to provide details about their water source and treatment goals. Our technical team can then assist in recommending the most effective and cost-efficient coagulant for your specific needs. When you buy from us, you gain access to expert advice and a reliable supply chain, ensuring optimal results for your water treatment processes.