A distribution unit for electric power and communications signals, particularly adapted to be used in combination weighers in order to supply power to individual heads of the weigher; the distribution unit is composed of a flexible printed circuit, which is manufactured flat and is provided with a plurality of multipole connectors for supplying power to the heads of a combination weigher and connect them to the communications network; the printed circuit is mounted on a substantially cylindrical structure, so that the multipole connectors are each arranged along a generatrix of the cylinder and the connectors of the weighing heads can be coupled to them radially.

A combinational weighing device is provided with a detection part detecting a measuring state on the basis of the quantity of a object introduced into each measuring hopper and a correction part operating a target dispersed weight defining the reference for control on a cross feeder by a supply control part. The correction part corrects the target dispersed weight in response to the measuring state of the combinational weighing device detected by the detection part. In other words, the correction part controls the quantity of the object supplied to a dispersion feeder on the basis of measured data indicating an actually measured value. Thus provided is a combinational weighing device performing efficient measurement without complicating the device structure.

A method and device for mixing and weighing fibrous material in a weighing cycle includes removing the fibrous material from fiber bales and transporting the fiber material with a feed device into a weighing container. The weighing container is proceeded by a pre-filling chamber that is separated from the weighing container by a controllable flap. After the fibrous material has been weighed, the material is ejected from the weighing container onto a mixing belt. The material feed device is controlled in accordance with a theoretical weight curve that is given for each fibrous material component. Transport speed of the material feed device is varied in accordance with the theoretical weight curve. The theoretical weight curve provides total weight of the transported fibrous material at a given time in the weighing cycle, and is determined for each fibrous material component based on a predetermined relationship of feed rate of the transported fibrous material as a function of time over the course of the weighing cycle in order to achieve a theoretical total weight of fibrous material to be transported into the weighing container during the weighing cycle.

A combinational measuring device is provided with a radiation feeder transporting objects and a measuring hopper measuring the weight of each group of objects transported by the radiation feeder. As to each measuring hopper performing introduction by a prescribed frequency, an average operation part obtains an average and standard deviation of a transport quantity every group transported by the radiation feeder. On the basis of the obtained standard deviation, a parameter operation part determines whether or not the transport quantity per group transported by the radiation feeder is dispersed. The parameter operation part operates a control parameter so that the transport quantity per group transported by the radiation feeder reaches a target introduction value if the transport quantity per group transported by the radiation feeder is stable, while operating the control parameter so that the transport quantity per group transported by the radiation feeder is not in excess of a target measured value if the transport quantity per group transported by the radiation feeder is dispersed. The combinational measuring device controls driving of the radiation feeder on the basis of the obtained control parameter. Thus, it is possible to provide a combinational measuring device performing efficient measurement.

A dosing device of a pulverulent material uses an oscillating drive mechanism with straight to-and-fro movement to extract and dose a pulverulent material contained in a hopper with a calibrated outlet aperture, and then to transfer the extracted mass to a removal point. The hopper can be fixed or movable. To measure the mass flowrate extracted from the aperture, the hopper is connected to the mechanism by a flexible blade and bears on a table equipped with a weighing cell formed by a weight sensor. The weight variation indicates the mass flowrate, which can be adjusted by acting on the oscillation frequency of the mechanism, or on the opening of the outlet aperture.