The present disclosure describes a method for producing insect and water mixture comprising providing and splitting a feedstock, introducing the feedstock into a plurality of insect feeding chambers to feed insects, removing insects from the plurality of insect feeding chambers, and introducing the insects to a mixing tank to produce the insect and water mixture including a biocatalyst and fermenting the insects for specific time durations, temperatures, pH, treated water, acid, a caustic material, and wherein the mixing tank is equipped with a mixer, baffles, and a heat exchanger. The insects may be grown with specific a feedstock diets, breeding methods, within shipping containers, and various operating and product parameters. The insect and water mixture can be filtered, spray dried, shaped, cooked, flavored, and used to prepare multifunctional flour compositions and foodstuffs.

The present disclosure discloses a high-content buckwheat dried noodle and a preparation method thereof, and belongs to the field of multi-grain flour products processing. The high-content buckwheat dried noodle of the present disclosure includes whole buckwheat flour, high-gluten wheat flour, vital wheat gluten, resistant starch, egg white powder, sodium alginate, konjac flour, sodium carbonate, glutamine aminotransferase, hemicellulase and phytase. The preparation method include: preprocessing a buckwheat raw material, optimizing a ratio of raw materials to auxiliary materials, and vacuum mixing, improved sheeting process, cutting, hanging, drying, strip shortening, packaging and other techniques and preparing high-content buckwheat dried noodles. By using the enzyme modification technique, the present disclosure improves protein cross-linking, increases soluble dietary fiber content, and biodegrades the anti-nutritional factor phytic acid, thereby effectively improving the utilization rate of nutrients, controlling the generation of post-prandial blood glucose and preventing obesity. Moreover, the high-content buckwheat dried noodle of the present disclosure includes no edible salt in its formula, is a healthy low-salt product which conforms to the concept of modern healthy diet.

The present disclosure discloses a high-content buckwheat dried noodle and a preparation method thereof, and belongs to the field of multi-grain flour products processing. The high-content buckwheat dried noodle of the present disclosure includes whole buckwheat flour, high-gluten wheat flour, vital wheat gluten, resistant starch, egg white powder, sodium alginate, konjac flour, sodium carbonate, glutamine aminotransferase, hemicellulase and phytase. The preparation method include: preprocessing a buckwheat raw material, optimizing a ratio of raw materials to auxiliary materials, and vacuum mixing, improved sheeting process, cutting, hanging, drying, strip shortening, packaging and other techniques and preparing high-content buckwheat dried noodles. By using the enzyme modification technique, the present disclosure improves protein cross-linking, increases soluble dietary fiber content, and biodegrades the anti-nutritional factor phytic acid, thereby effectively improving the utilization rate of nutrients, controlling the generation of post-prandial blood glucose and preventing obesity. Moreover, the high-content buckwheat dried noodle of the present disclosure includes no edible salt in its formula, is a healthy low-salt product which conforms to the concept of modern healthy diet.

In some examples, a system may be configured to generating flour having a uniform particle size of less than 100 Microns from whole insects. For example, the may include generating a slurry from whole insects by adding water while blending the whole insects using one or more mixers to generate an insect slurry. In some cases, the water is added to the insect parts to reduce the viscosity and to assist in separating the whole insects into parts. In some cases, the insect slurry may be filtered.

In some examples, a system may be configured to generating flour having a uniform particle size of less than 100 Microns from whole insects. For example, the may include generating a slurry from whole insects by adding water while blending the whole insects using one or more mixers to generate an insect slurry. In some cases, the water is added to the insect parts to reduce the viscosity and to assist in separating the whole insects into parts. In some cases, the insect slurry may be filtered.

Variable-scale, modular, easily manufacturable, energy efficient, reliable, and computer operated Insect Production Superstructure Systems (IPSS) may be used to produce insects for human and animal consumption, and for the extraction and use of lipids for applications involving medicine, nanotechnology, consumer products, and chemical production with minimal water, feedstock, and environmental impact. An IPSS may comprise modules including feedstock mixing, enhanced feedstock splitting, insect feeding, insect breeding, insect collection, insect grinding, pathogen removal, multifunctional flour mixing, and lipid extraction. An IPSS may be configured to be constructed out of a plurality of containerized modules.

Variable-scale, modular, easily manufacturable, energy efficient, reliable, and computer operated Insect Production Superstructure Systems (IPSS) may be used to produce insects for human and animal consumption, and for the extraction and use of lipids for applications involving medicine, nanotechnology, consumer products, and chemical production with minimal water, feedstock, and environmental impact. An IPSS may comprise modules including feedstock mixing, enhanced feedstock splitting, insect feeding, insect breeding, insect collection, insect grinding, pathogen removal, multifunctional flour mixing, and lipid extraction. An IPSS may be configured to be constructed out of a plurality of containerized modules.

Variable-scale, modular, easily manufacturable, energy efficient, reliable, and computer operated Insect Production Superstructure Systems (IPSS) may be used to produce insects for human and animal consumption, and for the extraction and use of lipids for applications involving medicine, nanotechnology, consumer products, and chemical production with minimal water, feedstock, and environmental impact. An IPSS may comprise modules including feedstock mixing, enhanced feedstock splitting, insect feeding, insect breeding, insect collection, insect grinding, pathogen removal, multifunctional flour mixing, liquid mixing, shaping, cooking, flavoring, biocatalyst mixing, exoskeleton separation, liquid separation, and lipid extraction. An IPSS may be configured to be constructed out of a plurality of containerized modules.

Variable-scale, modular, easily manufacturable, energy efficient, reliable, and computer operated Insect Production Superstructure Systems (IPSS) may be used to produce insects for human and animal consumption, and for the extraction and use of lipids for applications involving medicine, nanotechnology, consumer products, and chemical production with minimal water, feedstock, and environmental impact. An IPSS may comprise modules including feedstock mixing, enhanced feedstock splitting, insect feeding, insect breeding, insect collection, insect grinding, pathogen removal, multifunctional flour mixing, liquid mixing, shaping, cooking, flavoring, biocatalyst mixing, exoskeleton separation, liquid separation, and lipid extraction. An IPSS may be configured to be constructed out of a plurality of containerized modules.

In some examples, a system may be configured to generating flour having a uniform particle size of less than 100 Microns from whole insects. For example, the may include generating a slurry from whole insects by adding water while blending the whole insects using one or more mixers to generate an insect slurry. In some cases, the water is added to the insect parts to reduce the viscosity and to assist in separating the whole insects into parts. In some cases, the insect slurry may be filtered.