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.

A press apparatus for forming molded products is provided and includes a 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. 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.

A method of producing a solid soap containing at least one image embedded within the solid soap includes printing a printed image on a base layer of solid soap, applying molten soap to the printed base layer, and allowing the soap to harden so as to embed the image within the solid soap. The image can be a high-resolution image and can be printed on the base layer of solid soap using a flatbed printer. The soap can include a background layer against which the image is visible.

A method of producing a solid soap containing at least one image embedded within the solid soap includes printing a printed image on a base layer of solid soap, applying molten soap to the printed base layer, and allowing the soap to harden so as to embed the image within the solid soap. The image can be a high-resolution image and can be printed on the base layer of solid soap using a flatbed printer. The soap can include a background layer against which the image is visible.

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.

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.

The process immerses a plurality of smaller solids in a liquid softening/solvent/bonding agent (i.e. water, oils, solvent or some other combination). This reagent reacts with the solids over a period of time so that when the cavity containing the solid/liquid mixture is compressed, the solids and any other additives (i.e. oatmeal, spices, other foreign objects, etc . . . ) are forced together and force the liquid softening/solvent/bonding agent out. The expelled liquids are removed from the solids and additives which are then allowed to dry/bond/fuse thereby forming a solid bond. Whereas there is prior art utilizing aspects of this process specifically in soap scrap bonding, this method is the only method of compressing solids that does not require electricity and where the disparate solid pieces and the bonding agent/liquid are all contained in one vessel that enable the solids to react with the liquids and then be compressed removing the bonding agent/liquid and leaving only the solids which can then form a permanent bond, all in one device (see FIG. 8: Novel Mould Assembly , FIG. 10—Mould Assembly Option, FIG. 12—Novel Mould Assembly with Option Plunger Design). Furthermore, this design can incorporate the collection and if desired recycling of the reagent within the mould itself (i.e. a hollow cavity in the plunger and if necessary a collection vessel attached to the cap and/or stabilizing base). Finally, the plunger design allows the device to be used with or without any mechanical aids to prevent it from binding during longitudinal movement during compression of the mould/plunger. This, first of all, simplifies the mechanics of the device and allows the mould to be used by young and old alike regardless of ability.

This device will have applications in many industries but especially the craft industry (i.e. cheese making and soap making).

The process immerses a plurality of smaller solids in a liquid softening/solvent/bonding agent (i.e. water, oils, solvent or some other combination). This reagent reacts with the solids over a period of time so that when the cavity containing the solid/liquid mixture is compressed, the solids and any other additives (i.e. oatmeal, spices, other foreign objects, etc . . . ) are forced together and force the liquid softening/solvent/bonding agent out. The expelled liquids are removed from the solids and additives which are then allowed to dry/bond/fuse thereby forming a solid bond. Whereas there is prior art utilizing aspects of this process specifically in soap scrap bonding, this method is the only method of compressing solids that does not require electricity and where the disparate solid pieces and the bonding agent/liquid are all contained in one vessel that enable the solids to react with the liquids and then be compressed removing the bonding agent/liquid and leaving only the solids which can then form a permanent bond, all in one device (see FIG. 8: Novel Mould Assembly , FIG. 10—Mould Assembly Option, FIG. 12—Novel Mould Assembly with Option Plunger Design). Furthermore, this design can incorporate the collection and if desired recycling of the reagent within the mould itself (i.e. a hollow cavity in the plunger and if necessary a collection vessel attached to the cap and/or stabilizing base). Finally, the plunger design allows the device to be used with or without any mechanical aids to prevent it from binding during longitudinal movement during compression of the mould/plunger. This, first of all, simplifies the mechanics of the device and allows the mould to be used by young and old alike regardless of ability.

This device will have applications in many industries but especially the craft industry (i.e. cheese making and soap making).

An apparatus for production of a water-soluble shell for holding a filling substance, having a tank filled with a melt of a shell material, wherein the shell material contains a polymer and is water-soluble and is solid under standard conditions, and a male mold movably arranged in the region of the tank and automatically lowerable into the melt and withdrawable from the tank in order to form a water-soluble shell. The invention also relates to a corresponding process and to a corresponding shell and to a corresponding portion pack for use as a washing or cleaning agent.

A device for producing a water-soluble shell for receiving a filling substance, the device having a basin which is filled with a melt of a shell material, wherein the shell material is polymer-containing and water-soluble and solid under normal conditions, and a male mold which is movably arranged in the region of the basin, can be automatically submerged into the melt and can be removed from the basin in order to form a water-soluble shell optionally abutting the male mold. The invention also relates to a corresponding method and a corresponding shell and a corresponding portion for use as a washing or cleaning agent.