| Customization: | Available |
|---|---|
| CAS No.: | 9003-05-8 |
| Formula: | (C3h5no)N |
|
Still deciding? Get samples of $ !
Request Sample
|
Suppliers with verified business licenses
Audited Supplier Audited by an independent third-party inspection agency
| What is Anionic polyacrylamide (CPAM) ? |
| Polyacrylamide various percentages can be dissolved in water, especially when the concentration is higher than '70% more that are water-soluble polymers. Molecular Weight does not seem to affect the solubility of water, but the high molecular weight polymer at concentrations exceeding 10% will form a gel-like structure. This is due to the formation of intermolecular hydrogen bonds. (PAM) polyacrylamide insoluble in most organic solvents. Except for a few polar organic solvent, such as acetic acid,chloroacetic acid, ethylene glycol, glycerol, molten urea and formamide. However, the limited solubility of these organic solvents, often require heating, or of little value. Further soluble formamide, hydrazine, ethylene glycol. Because the industry in the form of an aqueous solution applications. |
Flocculation: The Key Process PAM excels by enabling suspended materials to coalesce through charge neutralization and bridge adsorption, resulting in efficient flocculation.
Adhesion: Binding Power Harnesses mechanical, physical, and chemical interactions to create strong bonds and effective action.
Reduction in Resistance: Efficiency Boost PAM is instrumental in drastically reducing fluid friction. Even minimal PAM presence in water can lower resistance by an astounding 50-80%.
Thickening: Amplified Viscosity PAM showcases its thickening prowess in both neutral and acidic settings. When the PH value exceeds 10, PAM undergoes hydrolysis, forming a semi-mesh structure for even more pronounced thickening.
Flocculation Principle: The Science Behind It PAM's flocculation ability is linked to floc surface characteristics, influenced by dynamic electromechanical interactions, PH value, viscosity, turbidity, and particle surface zeta potential. By introducing oppositely charged PAM, potential reduction and cohesion are achieved.
Adsorption Bridging: Linking Particles PAM's molecular chains anchor onto different particle surfaces, creating bridges that unite polymer particles, leading to aggregate formation and sedimentation.
Adsorption: Polar Connections PAM molecules interact with various polar groups, effectively capturing particles.
Enhancement: Strength and Structure The PAM molecular chain, when dispersed through various mechanical, physical, and chemical means, integrates with the dispersed phase, forming a reinforcing network that boosts the structural integrity.
){kind=link}