Draft:Polymer Modified Concrete

Submission rejected on 11 July 2024 by Ldm1954 (talk).

This submission is contrary to the purpose of Wikipedia.

Rejected by Ldm1954 24 days ago. Last edited by Ldm1954 24 days ago.

Comment: There already exists a page Polymer concrete. I moved the article to draft so you could improve it, and merge to the existing page but you decided not to. We do not duplicate pages, that is what redirects are for. Ldm1954 (talk) 12:58, 11 July 2024 (UTC)

Polymer Modified Concrete (PMC)

Introduction

Polymer Modified Concrete (PMC) is a variant of traditional concrete that has been enhanced with polymers. These polymers improve the concrete's properties, such as tensile strength, adhesion, and durability, making it more suitable for certain applications than traditional concrete.^[1]

History

The development of PMC began in the mid-20th century as a response to the need for more durable and versatile construction materials. The addition of polymers to concrete was found to significantly improve its performance in a variety of applications.^[1]

Composition

PMC is made by adding specific polymers to the concrete mix. These polymers can take the form of latex, re-dispersible polymer powders, or water-soluble polymers. The exact composition of PMC can vary depending on the desired properties and application.^[1]

Properties

The addition of polymers to concrete results in several enhanced properties. These include increased tensile strength, improved adhesion, and enhanced durability. PMC is also more resistant to chemicals and moisture than traditional concrete.^[1]

Applications

Polymer Modified Concrete is used in a variety of applications where traditional concrete may not be suitable. These include bridge deck overlays, repair and rehabilitation of existing structures, industrial flooring, waterproofing, and in environments that require extra resistance to abrasion and chemicals, such as tunnels and sewers.^[1]

Different PCMs have been studied in laboratories and on the field by the US Army Corps of Engineers© to assess performance between Polymer Modified Concrete and Polymer Cement Concrete solutions E-Krete Canada Mega-Patch and PermaStripe.^[2] at Edwards AFB. They noted the severely cracked asphalt surface upon which the PCM (E-Krete) was placed. Although many of the cracks have reflected back up through the PCM, it retained a better condition than the asphalt with little raveling unlike the surrounding pavement.

Advantages and Disadvantages

While PMC offers several advantages over traditional concrete, including higher tensile strength, superior adhesion, and greater resistance to chemicals and moisture, it also has some disadvantages. These include a higher cost compared to traditional concrete, more complex mixing and application processes, and the need for specialized knowledge for proper formulation and application.^[1]

Standards and Specifications

PMC must meet specific standards and guidelines to ensure its performance. These standards are provided by organizations such as ASTM International and the American Concrete Institute (ACI).^[3]

Conclusion

Polymer Modified Concrete represents a significant advancement in concrete technology. Its enhanced properties make it a valuable material in a variety of applications, and its use continues to grow as techniques and materials have continued to improve to this day.^[1]

References

^ ^a ^b ^c ^d ^e ^f ^g Ohama, Yoshihiko. Handbook of Polymer-Modified Concrete and Mortars: Properties and Process Technology. Noyes Publications, 1995.
^ Newman, J.K., Shoenberger, J.E. and POLYCON INC MADISON MS, 2003. E-Krete Canada (Trademark) Polymer Composite Micro-Overlay for Airfields: Laboratory Results and Field Demonstrations (No. ERDS/GSL-TR-03-24)
^ ASTM C1438 - 13 Standard Specification for Latex and Powder Polymer Modifiers for use in Hydraulic Cement Concrete and Mortar. ASTM International, 2013.

External links

[Ohama-1] ^ ^a ^b ^c ^d ^e ^f ^g Ohama, Yoshihiko. Handbook of Polymer-Modified Concrete and Mortars: Properties and Process Technology. Noyes Publications, 1995.

[Newman-2] Newman, J.K., Shoenberger, J.E. and POLYCON INC MADISON MS, 2003. E-Krete Canada (Trademark) Polymer Composite Micro-Overlay for Airfields: Laboratory Results and Field Demonstrations (No. ERDS/GSL-TR-03-24)

[3] ASTM C1438 - 13 Standard Specification for Latex and Powder Polymer Modifiers for use in Hydraulic Cement Concrete and Mortar. ASTM International, 2013.

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v t e Concrete
History	Ancient Roman architecture Roman architectural revolution Roman concrete Roman engineering Roman technology
Composition	Cement Calcium aluminate Energetically modified Portland Rosendale 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 Grinder Power trowel Pump Float Sealer Tremie
Science	Properties Durability Degradation Environmental impact Recycling Segregation Alkali–silica reaction
Types	AstroCrete Fiber-reinforced Filigree Foam Lunarcrete Mass Nanoconcrete Pervious Polished Polymer Prestressed Ready-mix Reinforced Roller-compacting Self-consolidating Self-leveling Sulfur Tabby Translucent Aerated AAC RAAC
Applications	Slab waffle hollow-core voided biaxial slab on grade Concrete block Step barrier Roads Columns Structures
Organizations	American Concrete Institute Concrete Society Institution of Structural Engineers Indian Concrete Institute Nanocem Portland Cement Association International Federation for Structural Concrete
Standards	Eurocode 2 EN 197-1 EN 206-1 EN 10080
See also	Hempcrete
Category:Concrete