A combined weighing system 1 includes a first X-ray inspection device 20, a combined weighing device 40, a bag making and packaging device 50, a weight inspection device 60, a second X-ray inspection device 70, and a management device 90 that manages each device. The management device 90 revises a weight conversion table of the first X-ray inspection device 20 and a correction value of the combined weighing device 40 based on an average value of weights of products B, which is calculated from a result of inspection over a certain time period in the weight inspection device 60.

A batching system (200) for use in a food packaging system comprises a batching table (202) having a plurality of filling stations (206) positioned around an axis of a predefined delivery position. A weigher (204) is operable to provide food product in predefined batches at the delivery position; and a conveyor (230) is provided for transporting said batches provided from the weigher (204) to at least one of said plurality of filling stations.

A batching system (200) for use in a food packaging system comprises a batching table (202) having a plurality of filling stations (206) positioned around an axis of a predefined delivery position. A weigher (204) is operable to provide food product in predefined batches at the delivery position; and a conveyor (230) is provided for transporting said batches provided from the weigher (204) to at least one of said plurality of filling stations.

When a combination calculator has selected both a first weighing hopper and a second weighing hopper corresponding to one feeding hopper, a controller drives a feeder so as to increase an amount of objects to be weighed that are held in the one feeding hopper, and then causes the one feeding hopper to discharge the objects to be weighed in both a first direction and a second direction concurrently to distribute the objects to be weighed to the first weighing hopper and the second weighing hopper that have been emptied.

When a combination calculator has selected both a first weighing hopper and a second weighing hopper corresponding to one feeding hopper, a controller drives a feeder so as to increase an amount of objects to be weighed that are held in the one feeding hopper, and then causes the one feeding hopper to discharge the objects to be weighed in both a first direction and a second direction concurrently to distribute the objects to be weighed to the first weighing hopper and the second weighing hopper that have been emptied.

<Problem> It is an object of the present invention to provide a timing hopper that inhibits the occurrence of the problem that articles end up getting stuck inside the timing hopper and are not normally discharged. <Solution> A timing hopper 9 includes a first member 91, a second member 92, and a gate 9a. The first member 91 has a first opening 91a to which articles A are input. The second member 92 has a second opening 92a from which the articles A are discharged. The gate 9a opens and closes the second opening 92a. The first member 91 has a first side wall 91b and a second side wall 91c. The second side wall 91c opposes the first side wall 91b. The second member 92 has a third side wall 92b and a fourth side wall 92c. The third side wall 92b is continuously connected to the first side wall 91b. The fourth side wall 92c opposes the third side wall 92b and is continuously connected to the second side wall 91c. The height position where the first side wall 91b and the third side wall 92b are interconnected is different from the height position where the second side wall 91c and the fourth side wall 92c are interconnected.

The present invention deals with a filling device (1) and a weighing device, wherein at least one 3D sensor (2) is provided to capture at least a partial area of the transport surface, virtually dividing the detected area into a plurality of sectors (3) and zones (4). The at least one sensor (2) is adapted to determine a distance to the measuring point as well as a respective angle of incidence at which the measuring point of the detected surface is measured, The filling device (1) is adapted to make a division into sectors (3) and zones (4) dynamically as a function of at least one influencing variable (E) to derive relevant information for the regulation of the control parameters therefrom in order to achieve a controlled product distribution.

The present invention deals with a filling device (1) and a weighing device, wherein at least one 3D sensor (2) is provided to capture at least a partial area of the transport surface, virtually dividing the detected area into a plurality of sectors (3) and zones (4). The at least one sensor (2) is adapted to determine a distance to the measuring point as well as a respective angle of incidence at which the measuring point of the detected surface is measured, The filling device (1) is adapted to make a division into sectors (3) and zones (4) dynamically as a function of at least one influencing variable (E) to derive relevant information for the regulation of the control parameters therefrom in order to achieve a controlled product distribution.

The present invention relates to a signal processing method for weight signals (W) of scales, in particular combination scales (K).

Signal processing is performed using preprocessed discrete values (W(i)) of the weight signal (W), which are supplied to at least one artificial neural network. With the help of this at least one artificial neural network, an estimated value (SW) for the actual weight is determined, for example in a weighing device of a combination scale. This is performed faster than if waiting for the actual weight signal. The estimated values (SW) are forwarded to the combination scale (KW), which uses them to form combinations.

A method for operating a mixing apparatus of a manufacturing plant comprises supplying multiple powdered products to the mixing apparatus. An inlet mass flow rate of the multiple powdered products into the mixing apparatus and a weight of the multiple powdered products in the mixing apparatus are measured. The multiple powdered products in the mixing apparatus are mixed to form a mixed product. The weight of the multiple powdered products in the mixing apparatus and an outlet mass flow rate of the mixed product from the mixing apparatus are predicted based on the measured inlet mass flow of the multiple powdered products. The predicted outlet mass flow rate of the mixed product from the mixing apparatus is corrected based on the measured weight of the multiple powdered products in the mixing apparatus. The mixed product is processed into final products