A method for producing a seed suspension (SSP) is disclosed, the method comprising the steps of: providing an edible fat (EDF) being melted, feeding said edible fat (EDF) through a processing zone (PZ), and performing a crystallization step in said processing zone (PZ) to obtain said seed suspension (SSP) by subjecting said edible fat (EDF) to a cooling temperature (CT) below 30 degrees Celsius in said processing zone (PZ), and subjecting said edible fat (EDF) to shear stress in said processing zone (PZ), wherein the edible fat (EDF) comprises SatOSat-triglycerides in an amount of 20 99% by weight. Also, a method of producing a heat stable chocolate, a seed suspension, a confectionary product, and a seed suspension apparatus is disclosed.

A method for producing a seed suspension (SSP) is disclosed, the method comprising the steps of: providing an edible fat (EDF) being melted, feeding said edible fat (EDF) through a processing zone (PZ), and performing a crystallization step in said processing zone (PZ) to obtain said seed suspension (SSP) by subjecting said edible fat (EDF) to a cooling temperature (CT) below 30 degrees Celsius in said processing zone (PZ), and subjecting said edible fat (EDF) to shear stress in said processing zone (PZ), wherein the edible fat (EDF) comprises SatOSat-triglycerides in an amount of 20 99% by weight. Also, a method of producing a heat stable chocolate, a seed suspension, a confectionary product, and a seed suspension apparatus is disclosed.

A method of forming a three-dimensional chocolate structure is disclosed wherein a mold is formed from blown sugar. A liquid fat layer is deposited onto the interior of the blown sugar mold. The mold is then cooled such that the liquid fat layer hardens. One or more layers of molten chocolate are deposited over the hardened liquid fat layer and allowed to cool and harden. The mold is then broken or cut so as to expose the three-dimensional chocolate structure therein. A number of chocolate structures can be formed and joined so as to create a complex chocolate structure.

A method of forming a three-dimensional chocolate structure is disclosed wherein a mold is formed from blown sugar. A liquid fat layer is deposited onto the interior of the blown sugar mold. The mold is then cooled such that the liquid fat layer hardens. One or more layers of molten chocolate are deposited over the hardened liquid fat layer and allowed to cool and harden. The mold is then broken or cut so as to expose the three-dimensional chocolate structure therein. A number of chocolate structures can be formed and joined so as to create a complex chocolate structure.

The use of ultrasound or acoustics applied at a level below that which causes cavitation to control the energy balance between particles and the liquid phase in a metastable liquid.

The use of ultrasound or acoustics applied at a level below that which causes cavitation to control the energy balance between particles and the liquid phase in a metastable liquid.

A method of predicting a temper level and/or a viscosity of a tempered mass, provided by tempering of a fat-containing, crystallisable mass, for example a chocolate mass, by flowing the mass successively through a temperer comprising an inlet, a crystallization stage to form crystals therein and a reheat stage to melt unstable crystals formed therein, is described. The method is implemented, at least in part, by a computer including a processor and a memory. The method comprises predicting the temper level and/or the viscosity of the tempered mass using a model, wherein the model relates the temper level and/or the viscosity of the tempered mass to one or more temperer process parameters. A method of controlling tempering and a temperer are also described.

A method of predicting a temper level and/or a viscosity of a tempered mass, provided by tempering of a fat-containing, crystallisable mass, for example a chocolate mass, by flowing the mass successively through a temperer comprising an inlet, a crystallization stage to form crystals therein and a reheat stage to melt unstable crystals formed therein, is described. The method is implemented, at least in part, by a computer including a processor and a memory. The method comprises predicting the temper level and/or the viscosity of the tempered mass using a model, wherein the model relates the temper level and/or the viscosity of the tempered mass to one or more temperer process parameters. A method of controlling tempering and a temperer are also described.