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

A soap reforming assembly includes a housing and a soap collection unit that is coupled to the housing for collecting and transporting pieces of soap when the pieces of soap are dropped into the housing. A heating element is coupled to the housing and the heating element heats the soap collection unit to melt the soap pieces into a fluid soap. A forming unit is positioned within the housing for receiving the fluid soap from the soap collection unit when the heating element produces the fluid soap. The forming unit cools and forms the fluid soap into a bar for bathing. A drawer is slidably positioned in the housing and the drawer receives the bar of soap from the forming unit. The drawer is positionable in an open position having the drawer extending outwardly from the housing to dispense the bar of soap.

A soap reforming assembly includes a housing and a soap collection unit that is coupled to the housing for collecting and transporting pieces of soap when the pieces of soap are dropped into the housing. A heating element is coupled to the housing and the heating element heats the soap collection unit to melt the soap pieces into a fluid soap. A forming unit is positioned within the housing for receiving the fluid soap from the soap collection unit when the heating element produces the fluid soap. The forming unit cools and forms the fluid soap into a bar for bathing. A drawer is slidably positioned in the housing and the drawer receives the bar of soap from the forming unit. The drawer is positionable in an open position having the drawer extending outwardly from the housing to dispense the bar of soap.

A cleansing composition includes 25% to 35% by weight of a surfactant, 1.5% to 5% by weight of a co-surfactant, 5% to 9% by weight of water; and 50% to 60% by weight of a fatty acid and soap mixture, wherein the fatty acid to soap ratio is 2.3:1 to 1.8:1. A method of making cleansing bars includes heating the cleansing composition to a temperature sufficient to provide a molten composition, cooling the molten composition to form flakes and/or chips, refining the flakes and/or chips to form billets, and stamping and/or cutting the billets to form the cleansing bars. Another method of making cleansing bars includes heating the cleansing composition to a temperature sufficient to provide a molten composition, pouring the molten composition into a mold, cooling the molten composition until the cleansing bars are formed, and removing the cleansing bars from the mold.

A cleansing composition includes 25% to 35% by weight of a surfactant, 1.5% to 5% by weight of a co-surfactant, 5% to 9% by weight of water; and 50% to 60% by weight of a fatty acid and soap mixture, wherein the fatty acid to soap ratio is 2.3:1 to 1.8:1. A method of making cleansing bars includes heating the cleansing composition to a temperature sufficient to provide a molten composition, cooling the molten composition to form flakes and/or chips, refining the flakes and/or chips to form billets, and stamping and/or cutting the billets to form the cleansing bars. Another method of making cleansing bars includes heating the cleansing composition to a temperature sufficient to provide a molten composition, pouring the molten composition into a mold, cooling the molten composition until the cleansing bars are formed, and removing the cleansing bars from the mold.

The present invention discloses a method of preparing a bactericidal, fungicidal and anti-allergenic Zanthoxylum schinifolium skin care soap, wherein the bactericidal, fungicidal and anti-allergenic Zanthoxylum schinifolium skin care soap comprises the following components based on percentage by weight: Component A: Zanthoxylum schinifolium seed oil 15.0-21.0%, propylene glycol 12.0-17.0%, glycerin 6.0-11.0%, Component B: deionized water 5.0-8.0%, sodium alkyl ether sulfate AES 8.0-12.0%, Component C: lauric acid 5.0-8.0%, stearic acid 11.0-16.0%, Component D: 98% NaOH 2.5-4.5%, deionized water balance, Component E: Zanthoxylum schinifolium essential oil 0.3-0.8%. The skin care soap of the present invention is pale yellow and translucent, has good stability, provides great aroma and rich foam, and can nourish the skin and sterilize effectively.

The present invention discloses a method of preparing a bactericidal, fungicidal and anti-allergenic Zanthoxylum schinifolium skin care soap, wherein the bactericidal, fungicidal and anti-allergenic Zanthoxylum schinifolium skin care soap comprises the following components based on percentage by weight: Component A: Zanthoxylum schinifolium seed oil 15.0-21.0%, propylene glycol 12.0-17.0%, glycerin 6.0-11.0%, Component B: deionized water 5.0-8.0%, sodium alkyl ether sulfate AES 8.0-12.0%, Component C: lauric acid 5.0-8.0%, stearic acid 11.0-16.0%, Component D: 98% NaOH 2.5-4.5%, deionized water balance, Component E: Zanthoxylum schinifolium essential oil 0.3-0.8%. The skin care soap of the present invention is pale yellow and translucent, has good stability, provides great aroma and rich foam, and can nourish the skin and sterilize effectively.

A soap reforming assembly includes a housing and a soap collection unit that is coupled to the housing for collecting and transporting pieces of soap when the pieces of soap are dropped into the housing. A heating element is coupled to the housing and the heating element heats the soap collection unit to melt the soap pieces into a fluid soap. A forming unit is positioned within the housing for receiving the fluid soap from the soap collection unit when the heating element produces the fluid soap. The forming unit cools and forms the fluid soap into a bar for bathing. A drawer is slidably positioned in the housing and the drawer receives the bar of soap from the forming unit. The drawer is positionable in an open position having the drawer extending outwardly from the housing to dispense the bar of soap.

A soap reforming assembly includes a housing and a soap collection unit that is coupled to the housing for collecting and transporting pieces of soap when the pieces of soap are dropped into the housing. A heating element is coupled to the housing and the heating element heats the soap collection unit to melt the soap pieces into a fluid soap. A forming unit is positioned within the housing for receiving the fluid soap from the soap collection unit when the heating element produces the fluid soap. The forming unit cools and forms the fluid soap into a bar for bathing. A drawer is slidably positioned in the housing and the drawer receives the bar of soap from the forming unit. The drawer is positionable in an open position having the drawer extending outwardly from the housing to dispense the bar of soap.

A bar soap recycling device including an enclosure assembly, a tray assembly, an electrical assembly, and a soap assembly is disclosed. These assemblies in conjunction with one another provide a simple solution to recycling used bars of soap. Leftover chips, slivers, or pieces of used soap bars are placed within a mold of the tray assembly. The tray assembly is placed within an enclosure that includes an integrated heating element. The heating element warms the heat conducting mold to the point of melting the used soap bars. A timer determines when the soap bars have had enough time to melt into the shape of the mold. A cooling element in the form of a fan then cools the mold and soap contained therein to resolidify the used bars of soap into a single bar. The resolidified bar of soap is then removed from the mold and ready to be used.