Polymer concrete

Polymer concrete is a type of concrete that uses polymer to replace lime-type cements as a binder. In some cases the polymer is used in addition to portland cement to form Polymer Cement Concrete (PCC) or Polymer Modified Concrete (PMC).^[1] Polymers in concrete have been overseen by Committee 548 of the American Concrete Institute since 1971.

Composition[]

In polymer concrete, thermoplastic polymers are often used,^[2] but more typically thermosetting resins are used as the principal polymer component due to their high thermal stability and resistance to a wide variety of chemicals. Polymer concrete is also composed of aggregates that include silica, quartz, granite, limestone, and other high quality material. The aggregate should be of good quality, free of dust and other debris, and dry. Failure to fulfill these criteria can reduce the bond strength between the polymer binder and the aggregate.^[3]

Uses[]

Polymer concrete may be used for new construction or repairing of old concrete. The adhesive properties of polymer concrete allow repair of both polymer and conventional cement-based concretes. The corrosion resistance and low permeability of polymer concrete allows it to be used in swimming pools, sewer structure applications, drainage channels, electrolytic cells for base metal recovery, and other structures that contain liquids or corrosive chemicals. It is especially suited to the construction and rehabilitation of manholes due to their ability to withstand toxic and corrosive sewer gases and bacteria commonly found in sewer systems. Unlike traditional concrete structures, polymer concrete requires no coating or welding of PVC-protected seams.^[4] It can also be used as a bonded wearing course for asphalt pavement, for higher durability and higher strength upon a concrete substrate, and in skate parks, as it is a very smooth surface.^{[citation needed]}

Polymer concrete has historically not been widely adopted due to the high costs and difficulty associated with traditional manufacturing techniques. However, recent progress has led to significant reductions in cost, meaning that the use of polymer concrete is gradually becoming more widespread.^[4]^[5]

Properties[]

The exact properties depend on the mixture, polymer, aggregate used etc.^[6] Generally speaking with mixtures used:

The binder is more expensive than cement
Significantly greater tensile strength than unreinforced Portland concrete (since polymer plastic is 'stickier' than cement and has reasonable tensile strength)^[1]
Similar or greater compressive strength to Portland concrete^[1]
Faster curing
Good adhesion to most surfaces, including to reinforcements
Good long-term durability with respect to freeze and thaw cycles^[1]
Low permeability to water and aggressive solutions
Improved chemical resistance
Good resistance against corrosion
Lighter weight (slightly less dense than traditional concrete, depending on the resin content of the mix)
May be vibrated to fill voids in forms
Allows use of regular form-release agents (in some applications)
Product hard to manipulate with conventional tools such as drills and presses due to its density. Recommend getting pre-modified product from the manufacturer
Small boxes are more costly when compared to its precast counterpart however pre cast concretes induction of stacking or steel covers quickly bridge the gap.

Specifications[]

Following are some specification examples of the features of polymer concrete:

Material	Density kg/m³	Compressive strength
Urea formaldehyde polymer concrete	2260^[7]	37 MPa (5,400 psi)^[8]
Polyester concrete	N/A	95 MPa (13,800 psi)^[9]
Epoxy concrete	N/A	58 MPa (8,400 psi)^[10]

References[]

^ Jump up to: ^a ^b ^c ^d Composite Structures for Civil and Architectural Engineering By D-H Kim
^ Figovsky, Oleg; Beilin, Dmitry (2013-12-11). Advanced Polymer Concretes and Compounds. ISBN 9781466590328.
^ L J Daniels, PhD Thesis, University of Lancaster, 1992 Polymer Modified Concrete
^ Jump up to: ^a ^b http://genevapolymerproducts.com
^ http://napsco.co
^ Concrete admixtures handbook : properties, science, and technology. V. S. Ramachandran (2nd ed.). Park Ridge, N.J., U.S.A.: Noyes Publications. 1995. ISBN 1-59124-038-7. OCLC 49708378.CS1 maint: others (link)
^ Design and manufacture of hybrid polymer concrete bed for high-speed CNC milling machine Jung Do Suh Æ Dai Gil Lee
^ The compressive strength of a new ureaformaldehyde-based polymer concrete A. A. Alzaydi, S. A. Shihata1 and T. Alp (in table Properties of polymer concrete)
^ Ohama, Y. (1997-04-10). Polymers in Concrete. ISBN 9780419223306.
^ "Power-Patch Concrete Epoxy Kit (Grey)". Interstate Products Inc. Retrieved 2021-06-04.

External links[]

Dayton Superior Corporation https://www.daytonsuperior.com

hide v t Concrete
History	Ancient Roman architecture Roman architectural revolution Roman concrete Roman engineering Roman technology
Composition	Cement Portland cement Water Water–cement ratio Aggregate Reinforcement Fly ash Ground granulated blast-furnace slag Silica fume Metakaolin
Production	Plant Concrete mixer Volumetric mixer Reversing drum mixer Slump test Flow table test Curing Concrete cover Cover meter Rebar
Construction	Precast Cast-in-place Formwork Climbing formwork Slip forming Screed Power screed Finisher Power trowel Pump Float Sealer Tremie
Science	Properties Degradation Environmental impact Recycling Segregation in concrete Alkali–silica reaction
Types	Energetically modified cement Fiber-reinforced Filigree Foam Lunarcrete Mass concrete Nanoconcrete Pervious Polished Polymer concrete Prestressed Ready-mix Reinforced Roller-compacting Ronsdale (natural) cement Self-consolidating Self-leveling Translucent concrete
Applications	Slab (waffle, hollow-core, voided biaxial, slab on grade) Concrete masonry unit Step barrier Roads Columns Structures
Organizations	American Concrete Institute Institution of Structural Engineers Indian Concrete Institute Nanocem Portland Cement Association International Federation for Structural Concrete
Standards	Eurocode 2 EN 206-1 EN 10080
Category:Concrete