Wholesale High Viscosity Hpmc - Hydroxypropyl Methyl Cellulose (HPMC) Used for Tile adhesives – MEVA
Wholesale High Viscosity Hpmc - Hydroxypropyl Methyl Cellulose (HPMC) Used for Tile adhesives – MEVA Detail:
Better Workability
The shear-thinning and air-entraining properties of HPMC give modified tile adhesives a better workability, as well as higher work efficiency, from yield/coverage and faster tiling sequence stand points.
Improves Water Retention
We can improve water retention in tile adhesives. This helps increase final adhesion strength as well as prolong open time. Prolonged open time also leads to faster tiling rate as it allows the worker to trowel a larger area before setting the tiles down, as opposed to troweling the adhesive onto each tile before setting the tile down.
Provides Slip/Sag Resistance
Modified HPMC also provides slip/sag resistance, so that heavier or non-porous tiles do not slip down the vertical surface.
Increases Adhesion Strengths
As mentioned before, it allows the hydration reaction to complete farther, thus allowing higher final adhesion strength to develop
Note:Products can be customized according to customer needs.
Product detail pictures:
Related Product Guide:
"Sincerity, Innovation, Rigorousness, and Efficiency" could be the persistent conception of our enterprise to the long-term to produce together with clients for mutual reciprocity and mutual profit for Wholesale High Viscosity Hpmc - Hydroxypropyl Methyl Cellulose (HPMC) Used for Tile adhesives – MEVA , The product will supply to all over the world, such as: Detroit, Georgia, Guinea, With a wide range, good quality, reasonable prices and stylish designs, our solutions are extensively used in beauty and other industries. Our solutions are widely recognized and trusted by users and can meet continuously changing economic and social needs.
By Griselda from Slovenia - 2017.08.15 12:36
We are old friends, the company's product quality has been always very good and this time the price is also very cheap.
By Honorio from Myanmar - 2018.02.21 12:14