Polymeric Resins

Withstand High Temperatures and Pressures

Polymeric resins are based on poly (styrene-divinylbenzene) resin manufacturing technology:

  • Polymeric resins as a solid extractant like bonded phase silica and activated carbon
  • Have large surface areas and fine pore structures
  • Effectively adsorb organic compounds from aqueous solutions
  • Stable in either acidic/strongly acidic
  • Stable in alkaline/strongly alkaline solutions, and organic solvents, from 1-14
  • Are easily regenerated for repeat use, increasing product life

Further, extraction processes with synthetic adsorbents reduce solvent usage and provide safer operations compared to conventional solvent extraction techniques.

Advantages Include:

  • Long lifetime
  • 10 to 1000 µm particle sizes
  • Wide array of pore sizes

Polymeric resins from Mitsubishi

Our high-quality Mitsubishi product includes PSDVB Ion-exchange resins/chelating resins, synthetic adsorbents and HPLC packed columns and packing materials. If interested in the Mitsubishi HPLC resins or columns, please call or email us.

Polymeric Resins have the highest extent of crosslinking and are made using proprietary processes which provide:

  • More strength to the gel
  • Stability at high pressures (30,000 psi)
  • Unparalleled resistance to shrinking and swelling
  • High pore volume (up to 750 m2/g)
  • Particle sizes ranging from 1-200 µm
  • High-temperature stability (150°C)
  • Pore sizes to cover the entire MW range
  • Widest range of polymeric surface chemistries (ion exchange, hydrophobic, hydrophilic)

Polymeric resins are substances made up of long chains of polymer molecules that are used in a variety of applications, including coatings, adhesives, and plastics. These materials are known for their versatility, strength, and durability, and they can be modified to suit a wide range of specific needs and requirements.

There are many different types of polymeric resins, including thermosetting resins, which harden and set when exposed to heat or other forms of energy, and thermoplastic resins, which can be melted and reshaped repeatedly without changing their chemical structure.

Some common examples of polymeric resins include epoxy resins, which are used as adhesives and coatings in a wide range of industries, including construction and automotive manufacturing; polyurethane resins, which are used in foam insulation, cushions, and coatings; and polyethylene resins, which are used to make a wide range of plastic products, including bottles, containers, and packaging materials.

Polymeric resins are also used in the production of composite materials, which are made by combining a resin with a reinforcement material, such as fibers or particles, to create a strong and lightweight material with unique physical and mechanical properties. Composite materials are used in a variety of applications, including aerospace, construction, and automotive manufacturing.