A method for preparing a substantially pasteurized and/or sterilized food product; the method, which can be used to produce pasta sauces or soups, comprises: a cooking step, during which a base of the food product is obtained by thermally treating a first component at a temperature exceeding 30° C.; a mixing step, during which said base and a second, substantially solid component are mixed together so as to obtain a mixture; and an ohmic treatment step, during which said mixture is subjected to an ohmic treatment so as to obtain the substantially pasteurized and/or sterilized food product.

A flash boiling apparatus for a liquid food product that includes particles, the apparatus including a vacuum vessel provided with a product inlet and a product outlet for liquid food product, a pressure relief valve arranged upstream the product inlet for providing a pressure drop that results in flash boiling of the liquid food product, and an inlet section arranged between the pressure relief valve and the product inlet, for conveying the liquid food product from the pressure relief valve to the product inlet. The inlet section includes a through-flow area that increases in a direction from the pressure relief valve to the product inlet, such that a flow velocity of the liquid food product decreases when it passes the inlet section.

A flash boiling apparatus for a liquid food product that includes particles, the apparatus including a vacuum vessel provided with a product inlet and a product outlet for liquid food product, a pressure relief valve arranged upstream the product inlet for providing a pressure drop that results in flash boiling of the liquid food product, and an inlet section arranged between the pressure relief valve and the product inlet, for conveying the liquid food product from the pressure relief valve to the product inlet. The inlet section includes a through-flow area that increases in a direction from the pressure relief valve to the product inlet, such that a flow velocity of the liquid food product decreases when it passes the inlet section.

A low-bacteria milk powder with a high WPNI is suggested, which is obtainable by (a) providing a raw milk; (b) heating the raw milk in at least one tubular heat exchanger to a temperature of at least 20° C.; (c) separating the cream, obtaining a skimmed milk; (d) pasteurising the skimmed milk in a tubular heat exchanger for a period from 10 to 60 seconds at a temperature from 72 to 75° C.; (e) evaporating the pasteurised skimmed milk to a dry matter content from 35 to 55% by weight; and (f) drying the pasteurised skimmed milk concentrate in a spray tower.

A low-bacteria milk powder with a high WPNI is suggested, which is obtainable by (a) providing a raw milk; (b) heating the raw milk in at least one tubular heat exchanger to a temperature of at least 20° C.; (c) separating the cream, obtaining a skimmed milk; (d) pasteurising the skimmed milk in a tubular heat exchanger for a period from 10 to 60 seconds at a temperature from 72 to 75° C.; (e) evaporating the pasteurised skimmed milk to a dry matter content from 35 to 55% by weight; and (f) drying the pasteurised skimmed milk concentrate in a spray tower.

Methods of heating compositions comprising at least 20% (w/w) individually distinguishable edible inclusions are provided herein. The method of heating as disclosed herein comprises applying a first ohmic heating treatment to the composition, wherein the composition has at the end of the first ohmic heating treatment a temperature from 60° C. to 95° C.; applying a first holding step to the composition, wherein the temperature of the composition is at most 5° C. lower than the temperature of the composition after the first ohmic heating treatment; applying a second ohmic heating treatment to the composition, wherein the composition has at the end of the second ohmic heating treatment a temperature ranging from 75° C. to 110° C.; and applying a second holding step to the composition, wherein the temperature of the composition is at most 5° C. lower than the temperature of the composition after the second ohmic heating treatment, wherein the steps are performed as a continuous process with an initial back pressure of at least 4 bar.

Methods of heating compositions comprising at least 20% (w/w) individually distinguishable edible inclusions are provided herein. The method of heating as disclosed herein comprises applying a first ohmic heating treatment to the composition, wherein the composition has at the end of the first ohmic heating treatment a temperature from 60° C. to 95° C.; applying a first holding step to the composition, wherein the temperature of the composition is at most 5° C. lower than the temperature of the composition after the first ohmic heating treatment; applying a second ohmic heating treatment to the composition, wherein the composition has at the end of the second ohmic heating treatment a temperature ranging from 75° C. to 110° C.; and applying a second holding step to the composition, wherein the temperature of the composition is at most 5° C. lower than the temperature of the composition after the second ohmic heating treatment, wherein the steps are performed as a continuous process with an initial back pressure of at least 4 bar.

A raw meat protein product is prepared by a process comprising directing a raw meat protein along a mixture conduit, placing steam in contact with the raw meat protein to raise the temperature of the raw meat protein to a pathogen neutralizing temperature, and maintaining that temperature in the raw meat protein for a treatment period of time. The process then includes applying a vacuum to the heated raw meat protein to vaporize water that has condensed from the steam and then separating the raw meat protein from the vaporized water and any remaining steam.

A raw meat protein product is prepared by a process comprising directing a raw meat protein along a mixture conduit, placing steam in contact with the raw meat protein to raise the temperature of the raw meat protein to a pathogen neutralizing temperature, and maintaining that temperature in the raw meat protein for a treatment period of time. The process then includes applying a vacuum to the heated raw meat protein to vaporize water that has condensed from the steam and then separating the raw meat protein from the vaporized water and any remaining steam.

A device for pasteurizing and filling medium into containers includes a short time heating system for pasteurizing the medium, a single buffer container downstream of the short time heating system for receiving the medium, and a rotary filling device downstream of the buffer container. The filling device is connected to the buffer container in a buffer-free manner and pipes and/or one or more rotary distributors are disposed between the filling device and the buffer container. A method for pasteurizing and filling medium into containers, where filling the containers with the medium is performed by way of a device in a buffer-free manner using a filling device, includes: pasteurizing the medium in the short time heating system, buffering the pasteurized medium in the buffer container, and filling the pasteurized medium into the containers. The pasteurized medium is transported in a buffer-free manner from the buffer container to the filling device.