A unit dose glass cleaner concentrate product includes from 5 grams to 50 grams of a concentrated glass cleaning composition encased in a water soluble film. The concentrated glass cleaning composition includes at least one cleaning solvent and at least one surfactant. The total weight percentage of the cleaning solvents and surfactants, expressed on an anhydrous basis, is at least 50% of the weight of the unit dose window cleaner concentrate product. The unit dose glass cleaner concentrate product can be added to a container and diluted to produce a glass cleaning solution.

Embodiments provide for an eco-friendly and non-toxic self-preserving liquid laundry detergent composition incorporating a blend of ingredients, at least some of which are multi-functional, thereby promoting both anti-stain and anti-odor functions while also contributing to composition preservation.

Liquid cleaning agent concentrate comprising: a. at least one fatty alcohol alkoxylate, b: at least one amino acid-based surfactant, c. at least one hydrotropic agent, and d. at least one enzyme, preferably proteolytic enzyme, a pH of the liquid cleaning agent concentrate being 9 or >9. The invention also relates to a ready-to-use solution; to uses thereof for cleaning and/or disinfecting objects and to cleaning methods.

The present invention relates to a pre-treatment composition for the cleaning of fabrics, especially a sprayable foamable liquid cleaning composition. It is an object of the present invention to provide a sprayable foamable liquid cleaning composition for the pretreatment of fabric which has superior soil removal properties for a wide variety of stains. It is yet another object of the present invention to provide a foamable cleaning composition having a pH of less than 4 which provides good stain removal benefits without compromising on the stability of the isotropic solution or foam structure. We have found that a foamable liquid composition providing a stable foam which exhibits dilutability, homogeneity in solution, excellent cleaning performance on various stain types can be prepared when higher levels of solvents and low pH are combined with specific amounts of alkoxylated anionic surfactant, nonionic surfactant, amphoteric surfactant and at specific ratios between the surfactant and solvents.

A method of treating a substrate comprising a first step of agitating a composition comprising solid particles comprising biodegradable polyester having a number-average molecular weight of from 10,000 Daltons to 500,000 Daltons, said solid particles having a size of from 0.1 mm to 100 mm; a liquid medium; and the substrate, and a second step comprising separating the solid particles from the substrate.

The present invention is directed to compositions, methods and systems for the removal of starch. The methods include: providing cleaning solution and rinsing fluid along supply line(s); connecting the supply line(s) to one or more cleaning applicators positioned to apply the cleaning solution or the rinsing fluid to one or more surfaces of a starch applicator system; and providing a controller which is able to control application of the cleaning solution and the rinsing fluid through the one or more cleaning applicators. The systems include the components described in relation to the methods. The compositions include about 5 to 15% w/w alpha amylase to break down the starch into water-soluble units; and non-ionic surfactant(s) and/or solvent(s) to react at the interface of the starch and surface it is attached to as well as liquify the resins.

The disclosure generally relates to a composition and process for cleaning residue and/or contaminants from microelectronic devices having said residue and contaminants thereon. The residue may include post-CMP, post-etch, and/or post-ash residue. The compositions and methods are particularly advantageous when cleaning a microelectronic surface comprising copper, low-k dielectric materials, and barrier materials comprising at least one of tantalum-containing material, cobalt-containing material, tantalum-containing, tungsten-containing, and ruthenium-containing material.

The present invention generally relates to a removal composition and process, particularly useful for cleaning ceria particles and CMP contaminants from microelectronic devices having said particles and CMP contaminants thereon, in particular microelectronic devices having PETEOS, Silicon Nitride, and Poly-Si substrates. In one aspect, the invention provides treatment of the microelectronic substrate having ceria particles thereon utilizing complexing agents free of Sulfur and Phosphorous atoms.

The present disclosure provides compositions for fabric treatment having at least one dye transfer inhibitor (DTI), at least one water-soluble carrier, at least one fragrance, and at least one buffer system, and other optional ingredients. During a wash cycle, the compositions disclosed herein significantly boost color fading protection of fabrics. The present disclosure further provides a method of making a composition for fabric treatment, including mixing a water-soluble carrier and a buffer system to form a mixture; adding a dye transfer inhibitor (DTI) and a fragrance into the mixture; mixing the mixture; heating the mixture and obtaining a melt thereby; and cooling the mixture. The method can further include shaping the melt into individual particles having melt bodies, which can optionally be in the form of a pastille.

Solid particulate compositions for fabric treatment having at least one cationic polymer, at least one water-soluble carrier, at least one fragrance, at least one buffer system, and other optional ingredients. During a wash cycle, the compositions deliver softening to the fabrics. The disclosure further provides a method of making a solid particulate composition for fabric treatment including: mixing a water-soluble solid carrier and a buffer system to form a mixture; wherein the solid carrier is an aqueous salt having a water vapor partial pressure at a temperature from about 30° C. to about 100° C. that corresponds to the water vapor partial pressure of a saturated solution of the salt at the same temperature; adding a cationic polymer and a fragrance into the mixture; mixing the mixture; heating the mixture and obtaining a melt thereby; and cooling and shaping the melt into individual particles including melt bodies.