A Parametric Disturbance Sensor is provided. The parametric disturbance sensor has a stripline enclosure having an internal chamber; a stripline sensor core positioned within the internal chamber; a fill material filling the internal chamber so that the stripline sensor is not in direct contact with the stripline sensor core enclosure; and a cable-end connector connected to the stripline sensor core for connecting the stripline sensor core to a processing unit.

Produce sorting systems and methods that utilize a conveyor system to move produce through stages such as singulation, camera inspection, weight, and sorting. The sorting systems and methods may utilize conveyor systems having carrier segments that provide for increased speed, efficiency, accuracy, reliability, durability, and lower maintenance.

A weighing apparatus includes: a transport unit capable of transporting an article; a weighing unit connected to the transport unit and configured to output an original signal related to a weight; and a weighing control unit configured to output a weighing value of the article by processing the original signal, wherein the weighing control unit is configured: to determine whether or not to adjust a zero point on the basis of a determination signal obtained by applying a first filter to the original signal; to generate an adjustment signal obtained by applying a second filter having more stages than the first filter to the original signal or the determination signal in a case where it is determined that the zero point is to be adjusted; and to perform adjustment of the zero point on the basis of the adjustment signal.

Weigh-in-motion sensors comprise a beam including a plate with a load-bearing surface, and a tube portion including a base wall and a cover and defining a cavity therebetween. A sensing package is disposed within the cavity and is under pre-load with the cover and the base wall. The sensing package comprises a piezoelectric element. The base wall includes an aperture extending from a mounting surface to the cavity. The aperture includes a fastener therein to secure the sensing package within the cavity. The fastener is sized having a cross-section dimension taken through a center axis of the fastener that is greater than that of a cross-section dimension of the piezoelectric element taken along the fastener center axis. In an example, the fastener has a cross-section dimension sized about 10 percent or greater in dimension than that of the respective cross-section dimension of the piezoelectric element.

A measurement method includes: a step of calculating, using first observation point information and based on a time from a leading time point when a leading part of a moving object passes a first observation point to a time point when each of a plurality of part passes the first observation point, and a time from the leading time point to a time point when a total sum of first physical quantities, which are responses to an action of each of the plurality of part on the first observation point, is distributed at a predetermined distribution ratio, a correction coefficient that corrects the first physical quantities; a step of calculating a deflection waveform of a structure generated by the plurality of parts based on the first observation point information, second observation point information, a predetermined coefficient, the correction coefficient, and an approximate expression of deflection of the structure; and a step of calculating a deflection waveform of the structure generated by the moving object by adding the deflection waveform of the structure.

An automated food slicing device is provided. The automated food slicing device may automate the cutting, packaging, and/or labelling of food items such as delicatessen food items. The automated food slicing device may also have a computerized input that allows a user to provide inputs regarding selected options which the slicing device will follow to provide a customized food product.

An endless conveyor device comprises a conveyor unit having at least one endless conveyor, which is configured to convey items; a drive roller assembly, which is drivable by a drive belt and configured to drive the endless conveyor and has a support element; a deflecting roller assembly and an intermediate body, disposed between the drive roller assembly and the deflecting roller assembly, as well as between a conveying strand and a return strand of the endless conveyor. The endless conveyor device further comprises a drive unit comprising the drive belt, a motor and a support device, which is configured to engage with the support element. The drive belt is relaxable by pivoting the conveyor unit relative to the drive unit about a rotation axis of the drive roller assembly in a first direction. A method for removing a conveyor unit from an endless conveyor device is also provided.

A Parametric Disturbance Sensor is provided. The parametric disturbance sensor has a stripline enclosure having an internal chamber; a stripline sensor core positioned within the internal chamber; a fill material filling the internal chamber so that the stripline sensor is not in direct contact with the stripline sensor core enclosure; and a cable-end connector connected to the stripline sensor core for connecting the stripline sensor core to a processing unit.

A packaging assembly including a sealing station for sealing a product with at least one film web, wherein a printer is provided upstream of the sealing station and configured to print information, in particular a product weight and an associated retail price, onto the film web or onto a label, which may already be present on the film web, wherein, upstream of the sealing station, a forward weighing device is provided and configured to detect a weight value of a product and forward it to a control unit. The packaging assembly is characterized in that the control unit controls the printer for printing-on the information depending on the detected weight value, and that, downstream of the sealing station, at least a first inspection device is provided to read the information on the imprint. A method for making the packaging assembly is also included.

A weighing system weighs an item within a container on a conveyor. The container is connected to the conveyor via a primary connecting means and a secondary connecting means, each of which include a first section permanently connected to the container, a second section permanently connected to the conveyor, and a third section hingedly connected to both the first section and the second section. The third sections are mutually coupled to each other, and are each rotatable about a first axis substantially parallel to the conveying direction, such that the rotation allows for movement of the container with respect to the conveyor in a vertical direction.