Bioplastic with Improved Strength and Thermal Performance

RTP Company has commercialized the industry’s first line of glass fiber-reinforced polylactic acid (PLA) compounds that overcome many limitations of unmodified PLA by delivering greater strength, stiffness, and thermal performance. These new materials, which target durable and semi-durable applications, are the latest extension of RTP Company’s family of engineered bioplastic compounds that use resins derived from rapidly renewable resources.

Global custom engineered thermoplastics compounder RTP Company has commercialized the industry’s first line of glass fiber-reinforced polylactic acid (PLA) compounds that overcome many limitations of unmodified PLA by delivering greater strength, stiffness, and thermal performance. These new materials, which target durable and semi-durable applications, are the latest extension of RTP Company’s family of engineered bioplastic compounds that use resins derived from rapidly renewable resources. PLA bio-polymers are a sustainable alternative to traditional hydrocarbon-based thermoplastics such as polyesters, polyolefins, and high-impact polystyrene. However, unmodified PLA suffers from performance limitations in terms of mechanical and thermal properties. “Our new glass fiber reinforced PLA compounds enhance the strength and temperature performance of PLA making it possible for PLA to be considered for much broader use,” said Will Taber, Business Manager for Emerging Technologies at RTP Company.

Fully colorable and available globally, RTP Company’s reinforced PLA grades have glass fiber loadings from 10% to 40% with the ability to customize glass level to meet the specific requirements of individual applications in appliance, automotive, consumer goods, electrical & electronics, and construction markets. The 30% glass fiber-reinforced PLA grade boasts a tensile strength of 16,500psi (114 MPa), flexural modulus of 1,630,000 psi (11,239 MPa), and heat deflection temperature (HDT) of 320°F at 66 psi (160°C at 455 kPa). In comparison to unmodified PLA, the compound has nearly twice the tensile strength and its HDT has increased by nearly 200°F (93°C). It surpasses the tensile strength, flexural modulus, and HDT of 30% glass fiber-reinforced polypropylene (PP). “RTP Company can now produce PLA bioplastic compounds with mechanical properties that meet or exceed those of many traditional thermoplastics,” said Taber. Proprietary nucleation packages speed crystallization which increases temperature performance and allows quicker part ejection, yielding PLA injection molding cycle times similar to PP and ABS. Several nucleating package option are available to balance cost and performance requirements. “We have really just begun to scratch the surface of what can be done with compounding PLA,” said Taber. Engineered bioplastic compounds from RTP Company provide additional material options for those looking to meet bio-based or renewable content requirements for product certifications such as EPEAT and LEED along with the European Cradle-to-Cradle initiative and USDA BioPreferred labeling program. RTP Company’s complete “Eco Solutions” product portfolio includes compounds that make use of bio-based or recycled resins, natural fibers, and halogen-free flame retardant or wear additives. These materials address the sustainability, re-utilization, and eco-conscious objectives of modern consumers and forward-thinking companies without compromising performance. (Source: Here)

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Call for Papers-13th international conference on fire science and engineering

The international organizing committee is pleased to make the 1st announcement and Call for Papers for the 13th international conference Interflam 2013.  For more details : Click Here

Ceramifying Polymers for Advanced Fire Protection

An interesting article :

Abstract: Ceramifying polymer materials have been developed by incorporating ceramic forming precursors into thermoplastics. These compounds can be processed on conventional plastic extrusion equipment to form sheets, profiles or coatings. In a fire situation, the polymer component is quickly pyrolized. However, a porous, coherent ceramic begins to form at sufficiently low temperatures to maintain the structural integrity of the material through to temperatures of over 1000°C. The ceramic forming systems can be adjusted to minimize dimensional changes, or to provide a degree of intumescence through entrapment of volatile gases from the polymer. This can produce a cellular structure with increased thermal resistance. Ceramifying polymer technology has already been commercialized for fire resistant cable coatings and shows promise for many other fire protection coating applications.

Article can be  free downloaded : Here

Developement of a new Non-halogenatdd FR

Consortium of Dutch companies (thermoplastics compounder, colorant house, molder, and OEM) joined together to develop colored and flame-retarded (FR) long-fiber thermoplastic (LFT)-polypropylene (PP) compounds and masterbatches, properties of which exceed those of non-FR base resin. Summing up work over last 2 years, TULiPPS’ Paul Stassen said this project exemplified what can happen when companies “join forces” to share knowledge, pool resources, and work as integrated supply chain. Original press release : Click here

Railway Transportation & Fire safety

The specialist industry magazine Railway Transportation International has published a number of articles presenting fire safety issues and solutions for railways (Source: Pinf).   Download magazine: Click Here

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