In a method for producing tablets for extraction of a liquid food product, dosed and moistened amounts of a powder ingredient are heated while contained in respective confined volumes. The method comprises the steps of: providing the ingredient in powder form; loading dosed amount of the powder ingredient into respective forming cavities; moistening each dosed amount of the powder ingredient, only at a surface layer thereof, and heating the dosed and moistened amount of the ingredient while contained in the respective forming cavity.

The present application relates generally to a process of manufacturing a plurality of products from chia seeds. The process comprises socking chia seeds in a large volume of water for a period of time followed by sonication at an elevated temperature to remove the soluble fiber, the mucilage of chia seeds using vacuum filtration. The oil component is extracted from mucilage removed chia seeds and the leftover is hydrolyzed in presence of an enzyme to afford a product of protein hydrolysates and a product of insoluble fiber of chia seeds. Both the process and the products are within the scope of this application.

Polyesters, such as those formed using polyols and di- or tri-carboxylic acids or anhydrides or salts thereof, are used as foam control agents in foodstuff processing. The polyesters are biodegradable and biocompatible while still providing excellent foam control capacity. In addition, polyesters foam control agents of the disclosure can be used with various apparatus while avoiding forming films that otherwise affect apparatus function. The polyesters can be used at various stages during industrial processing of vegetables (e.g., potatoes and beets) and fruits.

Polyesters, such as those formed using polyols and di- or tri-carboxylic acids or anhydrides or salts thereof, are used as foam control agents in foodstuff processing. The polyesters are biodegradable and biocompatible while still providing excellent foam control capacity. In addition, polyesters foam control agents of the disclosure can be used with various apparatus while avoiding forming films that otherwise affect apparatus function. The polyesters can be used at various stages during industrial processing of vegetables (e.g., potatoes and beets) and fruits.

In some embodiments, apparatuses and methods are provided herein useful to utilizing a sonication probe. In some embodiments, there is provided a rice cooker utilizing a sonication probe to cook rice including a rice cooker housing; a pH sensor; a temperature sensor; a viscosity sensor; a sonication probe; and a control circuit configured to control an operation of the sonication probe that causes the sonication probe to stop emitting one or more sound waves to substantially halt breakdown of amylose of the rice based on a pH value, a temperature value, and a viscosity value associated with the rice.

Some embodiments are directed to systems and methods for treating a viscous fluid. The viscous liquid may be a liquid sugar. The viscous fluid may have a viscosity of at least 50 cP. The system may include one or more mixers configured to receive the viscous fluid and to generate turbulent flow of the viscous fluid; and one or more UV chambers configured to receive the viscous fluid from the mixer and to expose the viscous fluid to a dose of UV light, the dose being at least 250 mJ/cm.sup.2. The system may deliver a total dose of UV light of about 500 mJ/cm.sup.2 such that bacteria and other contaminants are reduced or eliminated.

Embodiments described herein relate to methods of forming fibrous food products. In some aspects, a method can include mixing a composition with a solvent to form a first solution, the first solution including between about 15 wt % and about 40 wt % of the composition, the composition including a plant protein and a polysaccharide. The method further includes causing ejection of a second solution in a jet, collecting the jet of the second solution in a precipitation bath, such that a collection of fibers forms, drying the collection of fibers, and pulling apart the collection of fibers, and adding a fat and a flavoring to the collection of fibers to form the fibrous food product. In some embodiments, the method can further include heating the second solution to a temperature between about 40° C. and about 90° C. during the mixing and/or causing the ejection.

Embodiments described herein relate to methods of forming fibrous food products. In some aspects, a method can include mixing a composition with a solvent to form a first solution, the first solution including between about 15 wt % and about 40 wt % of the composition, the composition including a plant protein and a polysaccharide. The method further includes causing ejection of a second solution in a jet, collecting the jet of the second solution in a precipitation bath, such that a collection of fibers forms, drying the collection of fibers, and pulling apart the collection of fibers, and adding a fat and a flavoring to the collection of fibers to form the fibrous food product. In some embodiments, the method can further include heating the second solution to a temperature between about 40° C. and about 90° C. during the mixing and/or causing the ejection.

An anti-oxidation frying device includes a frying vessel having an electrically conductive body configured to heat cooking oil carried therein by a heating unit. A removable basket, also formed of electrically conductive material, is configured to be carried within the frying vessel to enable the cooking of food in the heated oil. A rectification circuit is coupled to the heating unit, the body of the frying vessel, and the basket. During operation the rectification circuit converts AC power from an external power source into a rippled, rectified AC current signal that is supplied to the heating unit, body of the frying vessel, and the basket, so as to create a reducing environment of available electrons for absorption by the cooking oil and food as it is prepared, thus extending the life of the cooking oil.

An anti-oxidation frying device includes a frying vessel having an electrically conductive body configured to heat cooking oil carried therein by a heating unit. A removable basket, also formed of electrically conductive material, is configured to be carried within the frying vessel to enable the cooking of food in the heated oil. A rectification circuit is coupled to the heating unit, the body of the frying vessel, and the basket. During operation the rectification circuit converts AC power from an external power source into a rippled, rectified AC current signal that is supplied to the heating unit, body of the frying vessel, and the basket, so as to create a reducing environment of available electrons for absorption by the cooking oil and food as it is prepared, thus extending the life of the cooking oil.