A cheesemaker with a container interior in the form of a cheese vat or cheese kettle, which rotatably incorporates a driven agitator with at least one agitating and cutting blade. The cheesemaker is to be simple in structural design and easy to operate, and also satisfy strict hygiene requirements. This is achieved by providing the agitating and cutting blade with a window that can be detached therefrom, and moved relative to the agitating and cutting blade.

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 food processing vat is provided with blade assemblies that extend from opposing sides of a rotating shaft. The blade assemblies may be curved or otherwise face different directions at different locations along their respective lengths. The vat may have a pair of rotating shafts and the rotation of the shafts may be timed so that the blade assemblies of the shafts simultaneously travel through a common swept volume. The blade assemblies may be positioned on the shafts so that they intermesh through each other while simultaneously moving through the common volume.

A food processing vat is provided with blade assemblies that extend from opposing sides of a rotating shaft. The blade assemblies may be curved or otherwise face different directions at different locations along their respective lengths. The vat may have a pair of rotating shafts and the rotation of the shafts may be timed so that the blade assemblies of the shafts simultaneously travel through a common swept volume. The blade assemblies may be positioned on the shafts so that they intermesh through each other while simultaneously moving through the common volume.

A method is disclosed for cutting cheese curd mass in a curd vat. A cutting apparatus is inserted into the vat before the curd mass is formed. A first cutting frame is used to cut the cheese curd in a first direction along one plane of the curd vat. The first cutting frame comprises one or more cutting wires extending in one or more directions. The method further comprises using a second cutting frame with one or more cutting wires extending in one or more directions. The second cutting frame operates in a second direction, wherein the second cutting operation removes the apparatus from the curd vat.

A method is disclosed for cutting cheese curd mass in a curd vat. A cutting apparatus is inserted into the vat before the curd mass is formed. A first cutting frame is used to cut the cheese curd in a first direction along one plane of the curd vat. The first cutting frame comprises one or more cutting wires extending in one or more directions. The method further comprises using a second cutting frame with one or more cutting wires extending in one or more directions. The second cutting frame operates in a second direction, wherein the second cutting operation removes the apparatus from the curd vat.

Systems and methods for monitoring a cheesemaking process, and for identifying certain stages of the process, are disclosed. The system includes a sonic sensor, along with a processor that will receive, from the sonic sensor, a signal that is indicative of a speed of sound in a material that is being processed in the cheesemaking process. The processor will use the speed of sound to identify a cut point in the cheesemaking process. The processor will generate a signal when the cut point is reached. Optionally, before this happens the processor also may use the speed of sound to identify a flocculation point in the cheesemaking process.

Systems and methods for monitoring a cheesemaking process, and for identifying certain stages of the process, are disclosed. The system includes a sonic sensor, along with a processor that will receive, from the sonic sensor, a signal that is indicative of a speed of sound in a material that is being processed in the cheesemaking process. The processor will use the speed of sound to identify a cut point in the cheesemaking process. The processor will generate a signal when the cut point is reached. Optionally, before this happens the processor also may use the speed of sound to identify a flocculation point in the cheesemaking process.

An apparatus for producing a food product is disclosed. The apparatus comprises: an enclosed vessel for holding the food product, the vessel having a first end wall, a second end wall opposite to the first end wall, and a side wall between the first and second end walls; a first agitator rotatably mounted to the first end wall, the first agitator extending inside the vessel towards the second end wall; and a second agitator rotatably mounted to the second end wall, the second agitator extending inside the vessel towards the first end wall. The first agitator is unsupported by the second end wall, and the second agitator is unsupported by the first end wall.

Systems and methods for monitoring a cheesemaking process, and for identifying certain stages of the process, are disclosed. The system includes a sonic sensor, along with a processor that will receive, from the sonic sensor, a signal that is indicative of a speed of sound in a material that is being processed in the cheesemaking process. The processor will use the speed of sound to identify a cut point in the cheesemaking process. The processor will generate a signal when the cut point is reached. Optionally, before this happens the processor also may use the speed of sound to identify a flocculation point in the cheesemaking process.