The present invention relates to a method of making a solid cleaning composition. The method can include pressing and/or vibrating a flowable solid of a self-solidifying cleaning composition. For a self-solidifying cleaning composition, pressing and/or vibrating a flowable solid determines the shape and density of the solid but is not required for forming a solid. The method can employ a concrete block machine for pressing and/or vibrating. The present invention also relates to a solid cleaning composition made by the method and to solid cleaning compositions including particles bound together by a binding agent.

A press apparatus for forming molded products is provided and includes an motive source and a press assembly in fluid communication with the motive source. The press assembly includes a press plate and a device configured to actuate axial movement of the press plate as initiated by the motive source. A mold base is positioned within the press assembly and configured for engagement with the press plate. The mold base includes a plurality of mold cavities and each of the mold cavities includes a mold cavity aperture. Each of the mold cavity apertures is arranged in a pattern and configured to provide access to a molded product positioned in a mold cavity. A release assembly is configured for engagement with the mold base and has a plurality of release fingers, each extending from a base plate. The plurality of release fingers is arranged in a pattern that aligns with the pattern of the mold cavity apertures.

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

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

A soap bar molding device for molding recycled soap bars includes a housing having a top surface and a bottom surface. Additionally, the housing has a front surface, a back surface, and an interior. A bottom plate is positioned on the top surface of the house and protruding inward therefrom. The bottom plate holds a plurality of soap pieces. An interior surface of a cover is positioned upon the top surface of the housing. A top plate is positioned on the interior surface of the cover. An exterior surface of the cover has a dish defining a space to hold a bar of soap. A power source is positioned within the interior of the housing. A button is positioned on the front surface of the housing and provides electric current from the power source to the bottom plate and the top plate wherein the bottom and top plates generate heat.

A soap bar molding device for molding recycled soap bars includes a housing having a top surface and a bottom surface. Additionally, the housing has a front surface, a back surface, and an interior. A bottom plate is positioned on the top surface of the house and protruding inward therefrom. The bottom plate holds a plurality of soap pieces. An interior surface of a cover is positioned upon the top surface of the housing. A top plate is positioned on the interior surface of the cover. An exterior surface of the cover has a dish defining a space to hold a bar of soap. A power source is positioned within the interior of the housing. A button is positioned on the front surface of the housing and provides electric current from the power source to the bottom plate and the top plate wherein the bottom and top plates generate heat.

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.

A soap remnant molding assembly includes a squeezer having a housing portion defining a chamber, and a handle portion engaged to the housing portion and extending outwardly from the housing portion. The molding assembly also includes a squeezer cover pivotally coupled to the squeezer and adapted to move between an open position and a close position. The squeezer cover includes a cover portion adapted to engaged with the housing portion and cover an access opening of the chamber in the close position of the squeezer cover, and a handle structure extending from the cover portion. A tray is removably arranged inside the chamber and includes a cavity to receive a plurality of soap remnants. The plurality of soap remnants arranged inside the cavity are pressed together to form a soap bar in response to the pivoting of the squeezer cover to the close position.

A soap remnant molding assembly includes a squeezer having a housing portion defining a chamber, and a handle portion engaged to the housing portion and extending outwardly from the housing portion. The molding assembly also includes a squeezer cover pivotally coupled to the squeezer and adapted to move between an open position and a close position. The squeezer cover includes a cover portion adapted to engaged with the housing portion and cover an access opening of the chamber in the close position of the squeezer cover, and a handle structure extending from the cover portion. A tray is removably arranged inside the chamber and includes a cavity to receive a plurality of soap remnants. The plurality of soap remnants arranged inside the cavity are pressed together to form a soap bar in response to the pivoting of the squeezer cover to the close position.

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.