Solid cleansing compositions and methods for the same are disclosed herein. The solid cleansing composition may include a soap and a plant oil. The plant oil may include flaxseed oil, and may be present in an amount effective to maintain or increase hydration of skin, inhibit inflammation of skin, deodorize skin, inhibit irritation of skin, or combinations thereof.

The present disclosure describes a peroxide based cleaning composition comprising a peroxide; a builder; a surfactant; a peroxide stabilizer; and remainder water and optional adjuvant. In various embodiments, the cleaning composition comprises hydrogen peroxide, sodium bicarbonate, a vegetable fatty acid potassium soap, glycerin, water and essential oil. The peroxide based cleaning composition exhibits storage stability for up to about 9-months and provides cleaning efficacy on a wide variety of hard surfaces and fabrics.

An electronic-device sanitizer product and method for sanitizing cellphones, smartphones, and other portable electronic devices, that is easy to carry, easy to find when needed, and easy to use, allowing frequent cleaning, having an alcohol-free sanitizing liquid, a misting sprayer, and a microfiber material for distributing and absorbing the sanitizing liquid, all enclosed in a slim tube-shaped package that can be carried on a keyring. Optionally, the sanitizing liquid can be provided with any of a number of distinctive scents that will be imparted to the electronic device.

A solid soap containing, (A) 77 to 91 mass % of an alkali metal salt of a saturated fatty acid having an even number of carbon atoms from 12 to 18, (B) 0.005 to 1 mass % of an alkali metal salt of a saturated fatty acid having an odd number of carbon atoms from 13 to 17, (C) 0.5 to 5 mass % of glycerol, and (D) 5 to 18 mass % of water.

The present invention is related to a sodium and potassium soap sponge and method of making it.

The invention relates to a process to make high water bars with a high speed extrusion process by using specific types and amounts of electrolytes in combination. The bars are produced with no negatives generally associated with use of electrolytes. Disclosed is an extruded soap bar composition wherein the bar comprises: a) 20 to 40% of water; b) 20 to 75% by wt. anhydrous soap; wherein C.sub.16 to C.sub.24 saturated soap comprises 12% to 45% by wt. of total bar. c) structurants comprises at least from 0.05 to 35% by wt., wherein the specific level of structurants is defined by the level of C16 to C24 saturated soap of (b) such that the total level of said C.sub.16 to C.sub.24 saturated soap and structurants are greater than 25%, and wherein said structurants are selected from the group consisting of starch, carboxymethylcellulose, inorganic particulates, acrylate polymers and mixtures thereof; d) electrolyte which is a combination of alkali metal chloride; and a secondary electrolytes selected from the group consisting of alkali metal citrate and alkali metal sulfate; and wherein the concentration of alkali metal chloride ([alkali metal chloride]); and of alkali metal citrate ([alkali metal citrate]), alkali metal sulfate ([alkali metal sulfate]) defined by level of water we use as follows: i. [alkali metal chloride]%=0.075×[water]−0.626; and ii. [alkali metal citrate]%=−0.0023×[water].sup.2+0.312×[water]−4.34; iii. [alkali metal sulfate]%=−0.0023×[water].sup.2+0.312×[water]−4.34; or iv. [alkali metal citrate and alkali metal sulfate]=−0.0023×[water].sup.2+0.312×[water]−4.34, wherein the calculated amount of the concentration of the electrolyte is plus or minus 15%.

Electrical devices for converting soap parts into bar soap or liquid soap including hopper for receiving the soap parts; means for increasing surface area of the soap parts by producing soap chips, the means for increasing the surface area being in communication with the hopper; mixing vessel for receiving the soap chips and forming a liquid soap mixture, the mixing vessel comprising means of agitation; liquid reservoir in fluid communication with the mixing vessel; ingredients reservoir in fluid communication with the mixing vessel; control unit having one or more processors; and non-transitory memory operatively coupled to the one or more processors comprising a set of instructions executable by the processors to cause the one or more processors to control various functions of the electrical device. The disclosure also relates to methods and systems for making bar soap and/or liquid soap using the machines and solutions for doing the same.

The invention relates to a process to make high water bars with a high speed extrusion process by using specific types and amounts of electrolytes in combination. The bars are produced with no negatives generally associated with use of electrolytes. Disclosed is an extruded soap bar composition wherein the bar comprises: a) 20 to 40% of water; b) 20 to 75% by wt. anhydrous soap; wherein C.sub.16 to C.sub.24 saturated soap comprises 12% to 45% by wt. of total bar. c) structurants comprises at least from 0.05 to 35% by wt., wherein the specific level of structurants is defined by the level of C16 to C24 saturated soap of (b) such that the total level of said C.sub.16 to C.sub.24 saturated soap and structurants are greater than 25%, and wherein said structurants are selected from the group consisting of starch, carboxymethylcellulose, inorganic particulates, acrylate polymers and mixtures thereof; d) electrolyte which is a combination of alkali metal chloride; and a secondary electrolytes selected from the group consisting of alkali metal citrate and alkali metal sulfate; and wherein the concentration of alkali metal chloride ([alkali metal chloride]); and of alkali metal citrate ([alkali metal citrate]), alkali metal sulfate ([alkali metal sulfate]) defined by level of water we use as follows: i. [alkali metal chloride] %=0.075×[water]−0.626; and ii. [alkali metal citrate] %=−0.0023×[water].sup.2+0.312×[water]−4.34; iii. [alkali metal sulfate] %=−0.0023×[water].sup.2+0.312×[water]−4.34; or iv. [alkali metal citrate and alkali metal sulfate]=−0.0023×[water].sup.2+0.312×[water]−4.34, wherein the calculated amount of the concentration of the electrolyte is plus or minus 15%.

A solid soap containing, (A) 77 to 91 mass % of an alkali metal salt of a saturated fatty acid having an even number of carbon atoms from 12 to 18, (B) 0.005 to 1 mass % of an alkali metal salt of a saturated fatty acid having an odd number of carbon atoms from 13 to 17, (C) 0.5 to 5 mass % of glycerol, and (D) 5 to 18 mass % of water.

Perfumed latex soap is prepared from the following components in parts by weight: 2-5 parts of natural latex, 5-12 parts of glycerin, 8-10 parts of sodium dodecyl sulfate, 5-10 parts of coconut oil, 6-8 parts of palm oil, 1-3 parts of titanium dioxide, 0.8-1.2 parts of ethylenediamine tetraacetic acid, 0.6-0.8 part of sulfur, and 0.8-1.0 part of radix asparagine essential oil. The perfumed latex soap is mild, safe, and non-irritating and has aroma of the natural latex. In addition, the added radix asparagine essential oil can effectively improve the skin condition of a human body without causing the human body to generate dependence. The temperature of the mixing tank in which the perfumed latex soup is prepared is convenient to adjust and materials in a mixing cylinder can be agitated and sheared during agitating, so that the materials are fully mixed and the quality of a product is improved.