Plastic is a material. This
plautic can be used in
to make Different Type of
material. an plastic
can be used ato make mate-
mial, like mulee, tumbler
mug, Qucket Make a
chart of fiul material
and the different object
which can be made outt
from there material
Answers
Answer:
Explanation:
Prototyping Plastic uses Fused Deposition Modeling (FDM) printers to produce prototypes. It is an ideal material for designers and engineers to cost-effectively produce and test a design and to get products to market faster. Its key characteristics are rapid turnaround time, economically priced, and form and fit prototyping. Its limitations include a tolerance of +/- 1-mm, overhangs that require support and affect surface finish, visible print layers, and anisotropy (weak in the Z direction). Prototyping plastic is most suitable for fit or form checks, but also for functional parts such as enclosures and custom piping.
Rigid opaque plastic is the leading material for delivering realistic prototypes with distinctive details, high accuracy, and a smooth surface finish with up to 16-micron layer heights. Its key strengths include fine-detail models with smooth surfaces, suitable for form and fit testing, convenient for sales and marketing demonstration models as well as its suitability for moving and assembled parts. Its one drawback is UV light sensitivity.
Rubber-like plastic makes it possible to simulate rubber with various levels of elastomer characteristics, which include Shore Scale A hardness, elongation at break, tear resistance, and tensile strength. The main technique used with Rubber-like plastic is laser sintering. Finished products such as toothbrushes, the non-slip or soft surfaces on consumer electronics, medical devices, and automotive interiors can be manufactured with Rubber-like plastic. It can be used in fashion design, models that require shock absorption, gadgets, squeezable models, and functional models. One drawback is its UV light sensitivity.
Transparent plastic is well suited for manufacturing translucent parts and prototypes with high precision. It is one of the most transparent 3D Printing materials on the market. Optimal for form and fit testing, transparent plastic offers a smooth surface finish that is ideal for fine-detail model construction of clear and tinted products such as eyewear, lighting covers, and medical devices. It is also particularly well suited for sales and marketing and medical/scientific demonstration models. One drawback is its sensitivity to UV light.
Polyamide for Selective Laser Sintering (SLA) 3D printing technique is a very fine, white, granular powder that employs laser sintering to produce complex, concept, and functional models as well as lamps and small series of models where several copies are reproduced. Laser sintering of polyamide delivers the greatest design freedom when compared with all other 3D Printing techniques. The final product results in a strong, relatively flexible object that can withstand small impacts and resist some pressure under bending constraints. The natural surface is slightly porous with a sandy, granular appearance, and multiple finishing possibilities exist. Polyamide objects can be finished with a satin, polished, or velvet surface or can be dyed or spray painted. They can also be sealed with a waterproof aqueous solution.
The different resins for use in 3D Printing include High-detail Resin, Mammoth Resin, Transparent Resin, Gray Resin, and Standard Resin. Each of these resins has its own specific characteristics and applications.
Photo-polymeric liquid is used to manufacture objects with High-detail Resin using PolyJet prototyping technology, stereolithography (SLA), and Digital Light Processing (DLP) technologies. High-detail Resin is particularly well suited for small and/or intricately detailed visual models. Models produced with