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.

Methods and systems for processing foods includes providing a flexible package. A pre-processed food product (e.g., raw food) is provided and is processed by rapidly heating the food product. This processed food product is delivered into the flexible package for consumption by a user. Additionally, in other embodiments, methods and systems for processing frozen food products to shelf stable or refrigerated products are provided. A frozen food product is provided, converted to a pumpable state, and then processed by rapidly heating the food product. This processed food product is then delivered into a package.

Methods and systems for processing foods includes providing a flexible package. A pre-processed food product (e.g., raw food) is provided and is processed by rapidly heating the food product. This processed food product is delivered into the flexible package for consumption by a user. Additionally, in other embodiments, methods and systems for processing frozen food products to shelf stable or refrigerated products are provided. A frozen food product is provided, converted to a pumpable state, and then processed by rapidly heating the food product. This processed food product is then delivered into a package.

A method for treating food where inside a packaging, made of a material configured for containing a gas-mixture, a food product and a gas mixture including at least carbon dioxide are inserted. Then, on the sealed packaging a uniform pressure, between 4 MPa and 20 MPa, is applied to compress the food. During application of the pressure, the packaging is maintained at a temperature between 25 C. and 50 C.

A method for treating food where inside a packaging, made of a material configured for containing a gas-mixture, a food product and a gas mixture including at least carbon dioxide are inserted. Then, on the sealed packaging a uniform pressure, between 4 MPa and 20 MPa, is applied to compress the food. During application of the pressure, the packaging is maintained at a temperature between 25 C. and 50 C.

A main energizing/heating unit has an outer electrode and an inner electrode, and energizes a fool material to be gelatinized by heating and continuously heat-treats it while it is conveyed in a food flow channel. The food flow channel in which the food material flows is formed between the both electrodes. Fed to the food material flowing in the food flow channel by a power supply section is a current in a direction traversing a flow direction of the food material. An inner cooling flow channel is formed in the inner electrode, and cooling liquid is fed to the inner cooling flow channel through a piping.

The invention relates to an apparatus for fast and homogeneously heating a liquid product to a heating temperature by means of resistive heating, the apparatus comprising at least two vertically mounted, longitudinal, heating chambers that are arranged in series.

The invention further relates to a process for fast and homogeneously heating a liquid product to a heating temperature by means of resistive heating in such apparatus comprising (a) continuously supplying the liquid product to the first heating chamber in series and flowing the liquid product continuously through the at least two heating chambers; (b) continuously generating an electrical current through the liquid product flowing through the heating chambers by continuously applying an electrical potential over each heating chamber, wherein the direction of the current is continuously alternated with a frequency of at least 500 Hz, to obtain heated liquid product; and (c) continuously discharging heated liquid product from the last heating chamber in series, wherein the liquid product has an electrical conductivity of at least 0.03 S/m.

The invention relates to an apparatus for fast and homogeneously heating a liquid product to a heating temperature by means of resistive heating, the apparatus comprising at least two vertically mounted, longitudinal, heating chambers that are arranged in series.

The invention further relates to a process for fast and homogeneously heating a liquid product to a heating temperature by means of resistive heating in such apparatus comprising (a) continuously supplying the liquid product to the first heating chamber in series and flowing the liquid product continuously through the at least two heating chambers; (b) continuously generating an electrical current through the liquid product flowing through the heating chambers by continuously applying an electrical potential over each heating chamber, wherein the direction of the current is continuously alternated with a frequency of at least 500 Hz, to obtain heated liquid product; and (c) continuously discharging heated liquid product from the last heating chamber in series, wherein the liquid product has an electrical conductivity of at least 0.03 S/m.

A system and method for defrosting a load are presented. Radio frequency (RF) signals are supplied to a transmission path that is electrically coupled to one or more electrodes that are positioned proximate to a cavity to cause the one or more electrodes to radiate RF electromagnetic energy. An RF power value of the RF signal along the transmission path is periodically measured resulting in RF power values and a rate of change of the RF power values is determined. A low-loss indicator value is determined using the RF power values, wherein the low-loss indicator value is at least partially determined by a dielectric loss of a load in the cavity. A controller determines, using the rate of change of the RF power values and the low-loss indicator value, that the load is in a defrosted state and stops supplying the RF signals.

A system and method for defrosting a load are presented. Radio frequency (RF) signals are supplied to a transmission path that is electrically coupled to one or more electrodes that are positioned proximate to a cavity to cause the one or more electrodes to radiate RF electromagnetic energy. An RF power value of the RF signal along the transmission path is periodically measured resulting in RF power values and a rate of change of the RF power values is determined. A low-loss indicator value is determined using the RF power values, wherein the low-loss indicator value is at least partially determined by a dielectric loss of a load in the cavity. A controller determines, using the rate of change of the RF power values and the low-loss indicator value, that the load is in a defrosted state and stops supplying the RF signals.