Described are very high molecular weight (e.g., over 2 million, such as 3-20 million g/mol) starch-based materials, and formulations including such, which can be spun in spunbond, melt blown, yarn, or similar processes. Even with such very high molecular weights, the formulations can be processed at commercial line speeds, with spinneret shear viscosities of 1000 sec.sup.−1, without onset of melt flow instability. The starch-based material can be blended with one or more thermoplastic materials having higher melt flow index value(s), which serve as a diluent and plasticizer, allowing the very viscous starch-based component to be spun under such conditions. The particular melt flow index characteristics of the thermoplastic diluent material can be selected based on what type of process is being used (e.g., spunbond, melt blown, yarn, etc.). The starch-based material may exhibit high shear sensitivity, strain hardening behavior, and/or very high critical shear stress (e.g., at least 125 kPa).

Fiber-containing composites are described that contain woven or non-woven fibers, and a cured binder formed from a binder composition that includes (1) a reducing sugar and (2) a crosslinking agent that includes a first carbon moiety selected from an aldehyde, a ketone, a nitrile, and a nitro group, wherein an α-carbon atom having at least one acidic hydrogen is directly bonded to the first carbon moiety. Exemplary reducing sugars include dextrose and exemplary crosslinking agents include glyoxal. Exemplary fiber-containing composites may include fiberglass insulation.

The present invention discloses a biodegradable polyester composition, wherein the biodegradable polyester composition comprises the following components in parts by weight: i) 58 to 80 parts by weight of an aliphatic-aromatic copolyester; ii) 20 to 32 parts by weight of starch; and iii) 0 to 10 parts by weight of a processing agent. The present invention unexpectedly found by research that by using an aliphatic-aromatic copolyester in which an amount of aromatic carboxylic acid accounts for a total amount of diacid is 44 mol % to 48 mol % as a matrix resin, where the aliphatic-aromatic copolyester has a crystallization peak width D of 5 C. to 16 C., and by using starch of which a particle size D (50) is 2 m to 12 m as the other phase, and meanwhile by adding a specific amount of a processing agent, the polyester composition prepared has excellent transversal and longitudinal tear strengths, and the polyester composition has a biodegradation rate of 90% or more during the 12-week degradation test, satisfying the industrial compost.

The chemical product packaging film of the present invention is a chemical product packaging film comprising a polyvinyl alcohol resin, a plasticizer, and water-soluble starch, the water-soluble starch having solubility in which the water-soluble starch dissolves when stirred in water having a concentration of the starch of 10% by mass at a temperature of 50 C. for 30 minutes, a content of the water-soluble starch being 4% by mass or less.

A method of forming a binder composition includes providing a urea-formaldehyde resin and combining one or more starch compounds with the urea-formaldehyde resin to form a starch modified urea-formaldehyde resin. The one or more starch compounds may be combined with the urea-formaldehyde resin so that the starch modified urea-formaldehyde resin includes about 1 wt. % to about 10 wt. % of the one or more starch compounds.

The present invention concerns a composition for the preparation of an elastomeric film. Furthermore, the present invention concerns the use of such a composition for the preparation of an elastomeric film, a method for preparing an elastomeric film and an elastomeric film produced by the inventive method.

A method is provided for manufacturing recyclable environment-friendly organic paper, in which a biomass plastic material, which is one of a biodegradable plastic (such as PLA), a biobased plastic (such as NPP), and a mixture of the two is used as a primary raw material, and the biomass plastic material and an inorganic mineral material (such as inorganic glass powder, mineral powder, and sand) and a bioplastic assisting agent (such as starch, apple pulp, egg shell, and the likes) are directly deposited into a compression and extension paper making machine to make environment-friendly organic paper. The environment-friendly organic paper so made does not contain fossil organic material (such as polypropylene), and thus no high temperature, smoke, and toxicant gases will be generated during burning and combustion and residuals of burning and combustion are primarily the natural inorganic minerals fraction can return to the earth and the nature.

Thermoplastic resin, especially in resin moldings whose main raw material is polyolefin-based resin, does not impair mechanical strength, water resistance, chemical resistance at the time of production, and does not require specific disposal means. Provided are a method for decomposing a resin molded body capable of decomposing a body and a degradable resin product. Decomposition treatment of a resin molded body that includes decomposing a resin molded body by applying a decomposition treatment liquid containing a plurality of fatty acid metal salts having different oxidation numbers by any method of coating, spraying, spraying or dipping a degradable resin product to which the decomposition treatment method is applied.

A container that dissolves. A shell defining the container sized to accommodate a volume of a consumable. The shell is water soluble. The shell defines walls extending upward from a closed bottom. The container includes a first water insoluble layer coating an exterior surface of the walls of the shell. One or more portions of the exterior surface are not coated with the first water insoluble layer promoting the dissolution of the container. The container includes a second water insoluble layer coating an interior of the shell.

Described herein are methods for increasing strength of blown films, by forming the films using a film blowing apparatus where the film is formed from a blend of a first polymeric material and a renewable carbohydrate-based polymeric material having particular characteristics. By using such a blend, and ensuring that the film blowing apparatus is operated at a high blow up ratio of at least 2.0, and/or using a narrow die gap of no more than 500 microns, Applicant has discovered that increased strength in the film can be obtained, as compared to where (i) the renewable carbohydrate-based polymeric material is not included or (ii) where the film is blown at lower blow up ratios and/or wider die gaps.