A method and a food processing system for distributing within a specific time interval a batch of a specific weight of food products onto the top surface of a dough base, such as a pizza base, cake base or the like the food processing system comprising a dosing mechanism, a weighing system, a conveyor system and a controller. The method comprises the steps of: i. defining a target time interval constituting 40-90 percent of the specific time interval, ii. determining the actual weight of the batch received within a receptacle of the weighing system when the target time interval has passed, iii. dependent on the actual weight, a. determining a first operational mode provided the actual weight being reached in respect of the target weight within the target time interval, then continuing operating the first conveyor controlled by the controller at the identical speed, or b. determining a second operational mode provided the actual weight exceeding the target weight within the target time interval, then operating the first conveyor controlled by the controller at a decreased speed, or c. determining a third operational mode provided the actual weight being below the target weight within the target time interval, then operating the first conveyor controlled by the controller at an increased speed.

Disclosed is an angle adjustment method for food blanks including: fixing a fixing device to a first corner of a wrapping skin at a first station; driving the fixing device to move to a second station by a moving driving member to drag the wrapping skin; and when dragging the wrapping skin, driving the fixing device to rotate by a rotation driving member. The present invention also provides an angle adjustment mechanism for food blanks for implementing the above method. The angle adjustment method and the mechanism for food blanks according to the present invention can adjust the angle of the food blanks and rotate the first corner of the wrapping skin to a specified angle to facilitate subsequent processing. Additionally, the wrapping skin has high angle adjustment accuracy, and the angle adjustment mechanism operates stably, avoiding damage to the wrapping skin.

A dough portioning device comprises a metering device with a container configured to receive a supply of dough, and a separator configured to separate a defined quantity of dough from the supply of dough and to discharge the quantity of dough at a discharge end of the metering device in a discharge direction. The dough portioning device furthermore comprises a conveyor device configured to transport dough in a conveying direction, wherein the conveyor device comprises a conveyor belt, and is arranged below the discharge end of the metering device. The conveyor device furthermore comprises a belt guide configured to bend/fold lateral sections of the conveyor belt relative to a middle section in a direction towards the metering device. The middle section of the conveyor belt has a declivity relative to the discharge end of the metering device, at least in a section in the region of the metering device.

A device for orienting wound dough products includes a first conveyor belt circulating with a first conveying speed and transporting a wound dough product having an end protruding from a circumference of the dough product. A second conveyor belt receives the wound dough product from the first conveyor belt and circulates with a second conveying speed which is different from the first conveying speed. The difference between the first conveying speed and the second conveying speed sets the wound dough product received from the first conveyor belt in a desired rolling motion on the second conveyor belt, wherein after the wound dough product has reached a defined end position in which the end of the wound dough product abuts on the second conveyor belt, the rolling motion of the wound dough product stops.

Frozen un-proofed dough pieces are produced by pinching an upper skin of an un-proofed dough body to a lower skin and producing a score through the upper skin prior to freezing. The un-proofed dough pieces are formed by mass production, with an un-proofed dough sheet being cut to form dough strips which are then cut into the un-proofed dough pieces, with the score for each un-proofed dough piece being formed either before, during or after the individual un-proofed dough pieces are actually created, but before freezing.

A dough stamping device for severing dough pieces from a dough sheet comprises a support, on which the dough sheet is depositable, and a blade assembly, which is configured to oscillate and perform indexed lifting actions in a substantially vertical direction. The blade assembly has a first group of blades, which is configured to at least partially generate an outer contour of a dough piece to be severed. In addition, the blade assembly has a second group of blades, which is configured to generate at least one slit inside of the outer contour of the dough piece.

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for a comestible loader with flatteners that pivot and translate. One of the methods includes receiving, by a comestible loader, a comestible through an opening defined in a loader frame of the comestible loader and onto a surface; and pivoting and translating a first flattener and a second flattener to a pre-press position to permit the first flattener and the second flattener to position the comestible approximately at a target position on the surface.

A device for orienting wound dough products includes a first conveyor belt circulating with a first conveying speed and transporting a wound dough product having an end protruding from a circumference of the dough product. A second conveyor belt receives the wound dough product from the first conveyor belt and circulates with a second conveying speed which is different from the first conveying speed. The difference between the first conveying speed and the second conveying speed sets the wound dough product received from the first conveyor belt in a desired rolling motion on the second conveyor belt, wherein after the wound dough product has reached a defined end position in which the end of the wound dough product abuts on the second conveyor belt, the rolling motion of the wound dough product stops.

A comestible processing machine including a loader plate comprising a plurality of spaced apart openings passing through the loader plate, a first flattener and a second flattener pivotably attached to the loader plate at each of the openings, a sensor configured to detect a comestible disposed within one or more of the plurality of openings, and an actuator coupled to the loader plate and configured to assist in removal of the comestible from the one or more of the plurality of openings.

A device for orienting wound dough products includes a first conveyor belt circulating with a first conveying speed and transporting a wound dough product having an end protruding from a circumference of the dough product. A second conveyor belt receives the wound dough product from the first conveyor belt and circulates with a second conveying speed which is different from the first conveying speed. The difference between the first conveying speed and the second conveying speed sets the wound dough product received from the first conveyor belt in a desired rolling motion on the second conveyor belt, wherein after the wound dough product has reached a defined end position in which the end of the wound dough product abuts on the second conveyor belt, the rolling motion of the wound dough product stops.