3D PRINTING FILAMENT PLA,

3D PRINTING FILAMENT NEAR ME

1. Reduced risk of cracks in the 3D print
2. Smoother surface finish, at a higher precision
3. Hardness improved 10 times over normal PLA
4. Stiffer, more glossy, and better colored.

Printing Settings:

Best Printing Temperature：200-220℃ Bed Temperature：0-70℃ Printing Speed：30~90mm/s Movement Speed：90~150mm/s Maintenance tips: Please put the unprinted material in sealed bags, then place it in a cool and dry place to prevent moisture. Please insert the wire into the fixed hole of the tray when you don’t use it in case of knotting. ABS will produce a slight irritating smell, please print in a well-ventilated environment.

Features:

Consistently High Quality Made from great, high-performance materials Ready to print on any open source desktop or industrial printer Deliver exceptional performance 100% bio-degradable and FDA food safety approved 10 times stronger than regular PLA on the market No wire-drawing problems, the surface of the printouts will be smoother and more delicate No cracking problem and brittle issue Low material shrinkage rate, uniform diameter

Package Includes:

1 x PLA+ 1.75mm 3D Printing Filament 1kg-Black GAAGS TECHNOLOGIES Pvt. Ltd. – Chennai, Tamil Nadu, India | Professional Profile | LinkedIn MORE INFO ABOUT PLA PLA polymers range from amorphous glassy polymer to semi-crystalline and highly crystalline polymer with a glass transition 60–65 °C, a melting temperature 130-180 °C, and a Young’s modulus 2.7–16 GPa.^[13][14][15] Heat-resistant PLA can withstand temperatures of 110 °C.^[16] The basic mechanical properties of PLA are between those of polystyrene and PET.^[13] The melting temperature of PLLA can be increased by 40–50 °C and its heat deflection temperature can be increased from approximately 60 °C to up to 190 °C by physically blending the polymer with PDLA (poly-D-lactide). PDLA and PLLA form a highly regular stereocomplex with increased crystallinity. The temperature stability is maximised when a 1:1 blend is used, but even at lower concentrations of 3–10% of PDLA, there is still a substantial improvement. In the latter case, PDLA acts as a nucleating agent, thereby increasing the crystallization rate.^[17] Biodegradation of PDLA is slower than for PLA due to the higher crystallinity of PDLA^{[citation needed]}. The flexural modulus of PLA is higher than polystyrene and PLA has good heat sealability. Several technologies such as annealing,^[18][19][20] adding nucleating agents, forming composites with fibers or nano-particles,^[21][22][23] chain extending^[24][25] and introducing crosslink structures have been used to enhance the mechanical properties of PLA polymers. Polylactic acid can be processed like most thermoplastics into fiber (for example, using conventional melt spinning processes) and film. PLA has similar mechanical properties to PETE polymer, but has a significantly lower maximum continuous use temperature.^[26] Racemic PLA and pure PLLA have low glass transition temperatures, making them undesirable because of low strength and melting point. A stereocomplex of PDLA and PLLA has a higher glass transition temperature, lending it more mechanical strength.^[27] The high surface energy of PLA results in good printability, making it widely used in 3D printing. The tensile strength for 3D printed PLA was previously determined.^[28] PLA is soluble in a range of organic solvents.^[29] Ethyl acetate is widely used because of its ease of access and low risk. It is useful in 3D printers for cleaning the extruder heads and for removing PLA supports. Other safe solvents include propylene carbonate, which is safer than ethyl acetate but is difficult to purchase commercially. Pyridine can be used, but it has a distinct fish odor and is less safe than ethyl acetate. PLA is also soluble in hot benzene, tetrahydrofuran, and dioxane.^[30] PLA FILAMENT,3D PRINTING FILAMENT PLA