A method and automated machine for milking dairy animals and manufacturing cheese from the milk obtained, including the steps of: milking a well-defined, measured amount of base milk which satisfies certain quality standards and which is not mixed with other milk; and manufacturing cheese directly from the base milk obtained, by means of a fully automatic production line, where the production line contains a number of separate processing locations where intermediate products from the base milk are generated and/or treated, and transportation between the processing location and the handling of the base milk is done by a fully automatic robot vehicle (robotised automatic guided vehicle).

Method and system for determining a specific mass flow rate of a highly viscous food product (1) having a viscosity of greater than 100 cP, which during processing in a continuous delivery flow is supplied to or removed from a buffer container (2) by means of a delivery pump (4) wherein a weighing device (7) is used to determine the change in the mass of the food product (1) in the buffer container (2) over a defined time period, which is in particular in the range of one or several minutes (Δm/Δt), wherein, in the same time period a pump parameter of the delivery pump (4) that is proportional to the expected delivery rate is registered, changes in the pump parameter over the time period are averaged to form an average pump parameter, wherein the current specific mass flow rate is calculated as a quotient from the change over time of the mass Δm/Δt and the averaged pump parameter and is output.

Method and system for determining a specific mass flow rate of a highly viscous food product (1) having a viscosity of greater than 100 cP, which during processing in a continuous delivery flow is supplied to or removed from a buffer container (2) by means of a delivery pump (4) wherein a weighing device (7) is used to determine the change in the mass of the food product (1) in the buffer container (2) over a defined time period, which is in particular in the range of one or several minutes (Δm/Δt), wherein, in the same time period a pump parameter of the delivery pump (4) that is proportional to the expected delivery rate is registered, changes in the pump parameter over the time period are averaged to form an average pump parameter, wherein the current specific mass flow rate is calculated as a quotient from the change over time of the mass Δm/Δt and the averaged pump parameter and is output.

A countertop cooking appliance is an apparatus that is used to manufacture food, particularly cheeses, with controlled heating, mixing, drainage, and pressure cycles. The apparatus is also configured to accept various cooking patterns for different foods based on different recipes. A perforated drainer is used to hold ingredients for mixing, completed cheese curds, and the finalized cheese product. A first receptacle is a container that holds the perforated drainer and temporarily stores whey and process byproducts. A second receptacle is a storage unit for whey and other liquid byproducts produced in the cheese development process. A fluid pump applies pressure to fluids collected in the first receptacle, transferring them to the second receptacle. A linear actuator provides mechanical power to one of several detachable food-interacting heads, which consequently chops, mixes, or otherwise agitates the contents of the perforated container.

A method and a control system of a food treating process made of a plurality of sub-processes is disclosed. The system comprises a plurality of product sensors including at least a spectrograph sensor and a thermograph sensor, plant sensors, control devices, a main hardware and software architecture apt, and a database structure to provide timely and automatic regulation controls, preferably exploiting synergies between various optimised parallel processes.

A method and a control system of a food treating process made of a plurality of sub-processes is disclosed. The system comprises a plurality of product sensors including at least a spectrograph sensor and a thermograph sensor, plant sensors, control devices, a main hardware and software architecture apt, and a database structure to provide timely and automatic regulation controls, preferably exploiting synergies between various optimised parallel processes.

Machinery for the production of pasta filata cheeses, including:—preparation cell adapted to receive the raw material, move it and heat it and then transfer it to a—spinning cell adapted to add water and steam, move and heat the mixture to the desired density and then transfer it to a—forming cell which receives the paste from the spinning cell, provided with timed augers and a thermometer to determine the moment in which to push the paste into a forming drum;—control unit, with software to monitor the cooking, spinning and forming conditions of the cheeses;—communication interface.

An auger assembly (1) for receiving and conveying cheese curd downstream along a cheese processing line (32) includes an auger housing (2), a first auger (3) having a first shaft (5) extending through the auger housing (2), a second auger (4) having a second shaft (6) extending through the auger housing (2) and arranged colinearly with the first shaft (5), a first bearing (9) mounted to the auger housing (2) and arranged at the end (7) of the first shaft (5), and a second bearing (10) mounted to the auger housing (2) and arranged at the end (8) of the second shaft (6). The first bearing (9) and second bearing (10) are colinear and facing each other. At least one slotted groove (11, 12) is formed the bearings (9, 10) to enable a cleaning fluid to contact a surface (13, 14) of the respective bearing (9, 10).

Forming machine to process stretched-curd cheeses including a frame to support feed device of stretched curd toward a forming roll having a plurality of cavities on its lateral surface, which are able to house respective portions of stretched curd, and associated with motor to drive the roll in rotation around its longitudinal axis, during the rotation of the forming roll each row of cavities being able to transit through at least an angular loading position and an angular unloading position, and separation device also being provided, interposed between the feed device and the forming roll in correspondence with the angular loading position in order to cut the portions of stretched curd housed inside the cavities from the remaining mass of stretched curd during the rotation of the forming roll; the cavities are distributed on a plurality of circumferential lines of the forming roll.

A milking system includes a milking device for milking a milking from a dairy animal. The system is provided with a control unit for the milking system, milking cups, a first milk jar for receiving the milking, a first pumping device for pumping the milking from the first milk jar to a first milk pipe, a second milk jar in flow communication with the first milk pipe for receiving the milking from the first milk jar, and a second pumping device for pumping the milking from the second milk jar into a second milk pipe. The first pumping device is configured to pump the milking at a first flow rate and the second pumping device is configured to pump the milking at a second flow rate, which is lower than the first flow rate. The milking system also includes a heat-exchanging system in flow communication with the second milk pipe.