The invention relates to a method for producing a milk-based product, comprising the steps of: providing a milk raw material; altering a ratio of casein to total protein of the milk raw material to less than about 0.80; subjecting the milk raw material with the altered ratio of casein to total protein from step b) to a heat treatment at the temperature of at least about 150° C. for a period of at most about 0.3 sec; cooling the heat-treated milk raw material from step c) to provide the milk-based product. The method provides milk-based products with long shelf life and good organoleptic properties.

The invention relates to a method of modification of dry matter composition and/or dry matter content of milk, comprising the steps of: providing raw milk having a fat content in the range of about 3% w/w to about 60% w/w; modifying a dry matter composition and/or dry matter content of the raw milk to provide a modified raw milk having a fat content in the range of about 35% w/w to about 60% w/w based on the total weight of the modified raw milk, and a protein content of at most 3% (w/w) and/or carbohydrate content of at most 4% (w/w) based on a fat-free portion of the modified raw milk. The invention further relates to a method of production of butter, wherein the milk with the modified dry matter composition and/or dry matter content is churned to provide butter.

Disclosed are methods for preparing dairy compositions using an ultrafiltration step and a nanofiltration step, followed by diafiltration of the nanofiltration retentate, and then at least one of a reverse osmosis and a forward osmosis step.

A method of preparing a low calorie, Lactose-free and Phosphorus-reduced milk with multiple filtration, centrifugation, carbonation and phase separation steps to remove Lactose and Phosphorus from milk including skim milk. The method includes a filtration apparatus to employ ultrafiltration to remove Lactose and any component of Lactose. Ultra-Centrifugation is used additionally to increase and complete the removal of Lactose and to facilitate the reduction of Phosphorous in the final milk preparation. The process eliminates the conventional use of lactase enzyme to hydrolyze Lactose into its simple sugar components.

Disclosed are processes for producing high protein, Greek yogurt products. Such processes can include a step of concentrating a skim milk product to produce a protein-enriched milk fraction, which then can be combined with one or more additional milk fractions to form a yogurt base. The yogurt base is inoculated with a yogurt culture and fermented, and at least a portion of the acid whey is removed from the fermented product using a ceramic ultrafiltration membrane system to form the Greek yogurt product.

A method for producing a first milk product having a first fat content and a second milk product having a second fat content. The method includes separating raw milk into cream and skim milk, diverting a first part of the cream into a first cream pipe, and a second part of the cream into a second cream pipe, dividing the skim milk in the main skim milk pipe, such that a first part of the skim milk flows into a first skim milk pipe and a second part of the skim milk flows into a second skim milk pipe. Flow rates for the two cream parts and the skim milk parts are determined, and valves are adjusted based on the determined flow rates, such that the milk products are obtained when mixing the cream and skim milk parts.

A method and system for processing a fermented dairy product, including feeding, in a product feed conduit, fermented dairy product to a separator, separating the fermented dairy product into a heavy phase and a light phase, returning a part of the light phase to the product feed conduit, such that the returned part of the light phase is mixed with fermented dairy product that is fed into the separator, while another part of the light phase is removed from the fermented dairy product, such that the heavy phase forms a concentrated, fermented dairy product.

A low-mineral quark matrix is suggested, which is obtainable by (a) subjecting raw milk to heat treatment, separating the cream, (b) subjecting the skimmed milk such obtained to an ultrafiltration step and/or a reverse osmosis step, producing a retentate R1, which represents a dairy protein concentrate, and a permeate P1, (c) subjecting the permeate P1 to an electrodialysis step, producing a salt-depleted diluate D1, (d) combining the diluate D1 with the retentate R1, (e) subjecting the combination product such obtained to heat treatment until denaturation sets in, (f) fermenting the denaturation product such obtained by the addition of starter cultures and rennet, and (g) adjusting or standardising the fermentation product such obtained to defined dry matter and protein contents.

A quark matrix having improved taste characteristics is suggested, which is obtainable by (a) subjecting raw milk to heat treatment, separating the cream, (b) subjecting the skimmed milk such obtained to a microfiltration step, obtaining a first retentate R1, which represents a first dairy protein concentrate, and a first permeate P1, (c) subjecting the permeate P1 to an ultrafiltration step and/or a reverse osmosis step, obtaining a second retentate R2, which represents a second dairy protein concentrate, and a second permeate P2, (d) subjecting the permeate P2 to an electrodialysis step, obtaining a salt-depleted diluate D1, (e) combining the diluate D1 with the retentate R1, (f) subjecting the combination product such obtained to heat treatment until denaturation sets in, (g) fermenting the denaturation product such obtained by adding starter cultures and rennet, and (h) adjusting the fermentation product such obtained to defined dry matter and protein contents.

A quark matrix having improved taste characteristics is suggested, which is obtainable by (a) subjecting raw milk to heat treatment, separating the cream, (b) subjecting the skimmed milk such obtained to an ultrafiltration step, a microfiltration step, and/or a reverse osmosis step, producing a high-protein retentate R1 and a high-lactose permeate P1 in the process, (c) enriching the retentate with an amount of lactose which corresponds to the amount that had been separated in the ultrafiltration step as permeate before, (d) subjecting the enrichment product such obtained to heat treatment until denaturation sets in, (e) fermenting the denaturation product such obtained by adding starter cultures and rennet, and (f) adjusting the fermentation product such obtained to defined dry matter and protein contents.