PNS (Poly Naphthalene Sulfonate)

  • Poly Naphthalene Sulfonate (PNS) is derived from coal tar processing. It can reduce the amount of water required to achieve a mid-range water reduction and a certain level of workability by up to 30%. Naphthalene sulfonate works by dispersing the cement particles and reducing the friction between them, which can improve the flow and workability of the concrete.

    The commonly used acronyms for PNS, which stands for Poly Naphthalene Sulfonate, in concrete admixtures are: PNSF which stands for Poly Naphthalene Sulfonate Formaldehyde, SNF stands for Sulfonated Naphthalene Formaldehyde, and FDN, stands for Formaldehyde Condensate of Naphthalene Sulfonic Acid.

  • Although commonly referred to as PNS (Poly Naphthalene Sulfonate), it is also used interchangeably with FDN (Formaldehyde-based Naphthalene Sulfonate Condensate) and SNF (Sodium Naphthalene Formaldehyde).

    PNS works by dispersing the cement particles and reducing the friction between them, which can improve the flow and workability of the concrete and can reduce the amount of water required to achieve a mid-range water reduction and a certain level of workability by up to 30%.

  • Poly Naphthalene Sulfonate (commonly called PNS) is derived from coal tar processing. It can reduce the amount of water required to achieve a mid-range water reduction and a certain level of workability by up to 30%. Naphthalene Sulfonate works by dispersing the cement particles and reducing the friction between them, which can improve the flow and workability of the concrete.

  • Overall, PNS plays a vital role in the manufacturing process of gypsum board, helping to improve the flow properties, workability, and quality of the final product. It is available in various forms and grades and can be tailored to meet the specific requirements of the production process.

    PNS (Poly Naphthalene sulfonate) is a commonly used water-reducing, flow, and dispersant additive in the manufacturing process of gypsum board (aka plasterboard and drywall).

    • As a water-reducing additive, PNS reduces the amount of water needed in the mixture to achieve the desired level of workability. This helps increase the final product’s strength and minimize the risk of shrinkage or cracking.
    • As a flow additive, PNS acts by improving the fluidity of the mixture and allowing it to be poured or pumped quickly and evenly. This results in a more uniform and consistent product with fewer defects or inconsistencies.
    • As a dispersant additive, PNS helps to create a stable and uniform dispersion of particles within the mixture, reducing clumping and promoting even distribution. This is particularly important in the case of gypsum boards, where uneven distribution can result in weak spots or inconsistent quality.
  • Although commonly referred to as PNS (Poly Naphthalene Sulfonate), it is also used interchangeably with FDN (Formaldehyde-based Naphthalene Sulfonate Condensate) and SNF (Sodium Naphthalene Formaldehyde).

    PNS works by dispersing the cement particles and reducing the friction between them, which can improve the flow and workability of the concrete and can reduce the amount of water required to achieve a mid-range water reduction and a certain level of workability by up to 30%.

  • In froth flotation, PNS (Poly Naphthalene Sulfonate) acts as an anionic surfactant commonly used as a collector in froth flotation. PNS has a hydrophobic (water-repelling) tail and a hydrophilic (water-attracting) head, which makes it an effective collector of hydrophobic minerals such as sulfides.

    PNS is added to the flotation cell’s slurry of ore and water. The PNS molecules attach themselves to the surface of the mineral particles, creating a hydrophobic surface. This makes the mineral particles more likely to attach to air bubbles and rise to the surface of the flotation cell, where they form a froth layer that can be skimmed off to produce a concentrate.

    PNS is effective in the flotation of various sulfide minerals, including zinc, copper, molybdenum, chalcopyrite, and galena. PNS can improve the recovery and grade of these minerals, resulting in a higher concentrate yield.

    PNS is a beneficial reagent in froth flotation, which can be explained as follows:

    • Adsorption: PNS molecules can adsorb onto the surfaces of mineral particles, particularly sulfide minerals such as chalcopyrite, sphalerite, and molybdenite. This adsorption is due to the hydrophobic nature of the PNS molecule and the presence of sulfonic acid groups that can form hydrogen bonds with the mineral surface.
    • Frothing: PNS can also act as a frothing agent in froth flotation, helping to create a stable froth that can carry the mineral particles to the surface. This is because PNS molecules can lower the surface tension of the water in the flotation cell, allowing gas bubbles to form and stabilize.
    • Selectivity: PNS can improve the selectivity of mineral separation by preferentially adsorbing onto the surfaces of certain minerals. This can be particularly beneficial in complex ores containing multiple minerals with similar properties.
    • Higher concentrate yield: PNS can improve concentrate yield in zinc, copper, molybdenum, and other ores by increasing the recovery of valuable minerals. This is due to the increased adsorption of the PNS molecules onto the mineral surfaces, which can increase the probability of the froth collecting the mineral particles.
    • Cost-effectiveness: PNS is a relatively inexpensive reagent easily incorporated into froth flotation processes. This can lead to cost savings in the production of minerals, particularly in large-scale mining operations.

    References:

    • Zhang, H., Guo, X., Wang, H., Chen, H., & Li, H. (2019). The role of poly naphthalene sulfonate on copper sulfide flotation. Minerals Engineering, 143, 105898
    • Liu, Y., Hu, Y., Huang, Q., & Liu, W. (2019). Influence of poly naphthalene sulfonate on the flotation separation of molybdenum and copper sulfides. Minerals Engineering, 135, 24-30.
    • Liu, J., Sun, W., Hu, Y., & Cui, W. (2018). Flotation of copper oxide minerals using ethylene diamine tetra-acetic acid as an activator. Minerals Engineering, 117, 20-24.
    • Yang, Q., Li, Y., Han, J., Wen, L., Liu, Q., & Li, W. (2021). Selective flotation of copper and lead sulfide minerals in mixed sulfide ore using poly-naphthalene sulfonate. Minerals Engineering, 172, 107112.
    • Wang, L., & Forssberg, K. S. E. (1995). Effect of polymeric dispersants on sulfide ore flotation. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 96, 121-129.

    PNS can also be utilized to handle mine tailings, which are the waste materials left over after the extraction of minerals from the ore. A challenge in managing mine tailings is their transportation and deposition in tailing ponds or other storage facilities. Tailings can be very dense and difficult to pump and place in a controlled manner, leading to issues such as blockages, overflow, and environmental damage.

    PNS can be used as a dispersant in handling mine tailings, which can help break up the dense particles and improve the flowability of the slurry. This can make it easier to pump the tailings over long distances and deposit them in a controlled manner, reducing the risk of blockages and overflow.

    Water Reduction improvements in the handling of mine tailings, through the use of PNS, can also have environmental benefits. By improving the flowability of the slurry, less water may be required in the transportation and deposition process, reducing the amount of freshwater needed and the potential for water pollution.

  • Polynaphthalene Sulfonate, Polyβ-naphthol Sulfonate, and Polymelamine Sulfonate are all examples of commonly used dispersants. These dispersants function by repelling particles and keeping them suspended in the cement slurry. Still, they have different chemical structures and may exhibit different levels of effectiveness depending on the specific application.

    In addition to reducing viscosity and improving pumpability, dispersants can also improve fluid loss control and prevent the formation of channels in the cement sheath. This can help to ensure proper zonal isolation and reduce the risk of unwanted fluid migration.

    The use of dispersants in oil well cementing and fluid loss control systems can improve the quality and reliability of the cementing operation by ensuring proper placement and preventing issues such as lost circulation and poor zonal isolation.

  • PNS (Poly Naphthalene Sulfonate) is a chemical compound used in water treatment applications. It is a water-soluble polymer that is derived from naphthalene sulfonic acid.  PNS is used to disperse solids in water, preventing them from settling and forming deposits on pipes and equipment.

    The benefits of using PNS in water treatment include:

    • Effective: PNS is an effective dispersant and water-reducing agent in water treatment. It can help to prevent deposits from forming on pipes and equipment and make solids easier to remove from the water.
    • Versatile: PNS can be used in various water treatment applications, including industrial water treatment, municipal water treatment, and agriculture.
    • Environmentally friendly: PNS is considered environmentally friendly as it is biodegradable and non-toxic.
    • Cost-effective: PNS is a cost-effective option for water treatment. It is readily available and is often less expensive than other water treatment chemicals.