Biodegradable polymer blends and composites from renewable resources

“…A Scanning Electron Microscopy (Make: Hitachi High‐Technologies Europe GmbH, Germany) operated at 15 kV was used to record the micrographs of the additives before processing. [ 46,47 ]…”

“…(B) 3D printing of continuous fiber reinforcement (C) Carbon fiber reinforced thermoplastic photograph [38] 15 kV was used to record the micrographs of the additives before processing. [46,47] The samples were printed as per the ASTM D638 standard, which specifies the Type V dimensions, and then tested to ensure that they met the tolerance criteria. Samples were manufactured on a single platform to avoid temperature variations that may have occurred inside the machine's construction envelope.…”

Additive manufacturing of jute fiber reinforced polymer composites: A concise review of material forms and methods

“…A Scanning Electron Microscopy (Make: Hitachi High‐Technologies Europe GmbH, Germany) operated at 15 kV was used to record the micrographs of the additives before processing. [ 46,47 ]…”

“…(B) 3D printing of continuous fiber reinforcement (C) Carbon fiber reinforced thermoplastic photograph [38] 15 kV was used to record the micrographs of the additives before processing. [46,47] The samples were printed as per the ASTM D638 standard, which specifies the Type V dimensions, and then tested to ensure that they met the tolerance criteria. Samples were manufactured on a single platform to avoid temperature variations that may have occurred inside the machine's construction envelope.…”

Additive manufacturing of jute fiber reinforced polymer composites: A concise review of material forms and methods

“…Nowadays, a variety of naturally derived polymers are accessible for application in the form of biomaterials. Examples include polysaccharides derived from plants, animals, fungi and bacteria, as well as proteins, lipids/surfactants, and other polymers (Rajeshkumar, 2022). Importantly, many of these polymers are extracted from sources which could be used for human consumption.…”

Edible hyaluronic acid‐rich burger separator discs prepared from slaughterhouse waste

“…The performance of these bio-based composites is good and reasonable in applications, where regulated fiber orientation is needed. 19 Bioplastics are made from wasted, including tropical tree fruit, 20 banana waste, 21,22 food scraps, 23 agriculture waste, 24 paper waste, 25,26 oil seeds' empty fruit bunch, 27 sugarcane, 28 cornflour, 29,30 starch, 31,32 husks, 33 canola oil, 34,35 cooking oil, 36 soy protein, 37 organic matter from flowers, seedlings, and carbohydrates. 38,39 Polylactic acid (PLA) is used as a substrate for the development of biocomposites for packaging applications.…”

Synthesis and thermomechanical properties of bioplastics and biocomposites: a systematic review