3.3—Polymer materialsThe improvemen

3.3—Polymer materials
The improvement of properties of hardened concrete by
the addition of polymers is well documented. A bibliography
of major references covering polymers in concrete and a
glossary of terms are included in ACI 548.1R. This guide
presents information on various types of polymer materials
and their storage, handling, and use, as well as on concrete
formulations, equipment to be used, construction procedures,
and applications.
Two basic types of concrete materials use polymers to
form composites: polymer-cement concrete (PCC) and
polymer concrete (PC).
3.3.1 Polymer-cement concrete and mortar—
Polymer-cement concrete (PCC) has, at times, been called
polymer-portland-cement concrete (PPCC) and latex-modified
concrete (LMC). It is identified as portland cement and
aggregate combined, at the time of mixing, with organic
polymers that are dispersed or redispersed in water. This
dispersion is called a latex, and the organic polymer is a
substance composed of thousands of simple molecules
combined into large molecules. The simple molecules are
known as monomers, and the reaction that combines them is
called polymerization. The polymer may be a homopolymer
if it is made by the polymerization of one monomer, or a
copolymer if two or more monomers are polymerized.
In this section, the use of PCC includes both mortar and
concrete.
Polymer dispersions are added to the concrete mixture to
improve the properties of the final product. These properties
include improved bond strength to concrete substrates,
increased flexibility and impact resistance, improved
resistance to penetration by water and by dissolved salts, and
improved resistance to freezing and thawing.
Of the wide variety of polymers investigated for use in
PCC, polymers made by emulsion polymerization have been
the most widely used and accepted (ACI 548.3R). Styrene
butadiene and acrylic latexes have been the most effective and
predictable for concrete restoration. Other latexes commonly
used include polymers and copolymers of vinyl acetate.
When emulsified and mixed with concrete, epoxies provide
excellent freezing-and-thawing resistance, significantly
reduced permeability, and improved chemical resistance.
Bond is excellent, and flexural, compressive, and tensile
strengths are high. Epoxy emulsions, however, have had
limited use in concrete.