A monoblock sensor body of a load cell based on an electromagnetic force compensation mechanism has a Roberval mechanism. Mounting portions mount the fixed column to a housing side of a weighing module, and mount a load receiving member to the movable column. At least one of the mounting portions has at least one mounting hole that extends predominantly orthogonal to the load direction. One of the flexure point sections is closest to the mounting hole. A cavity associated with at least one of the mounting portions reduces an available solid angle for straight propagation paths that run from the inner thread to one or more of: the closest flexure point section, the coupling and the closest fulcrum. A material boundary of the body closes the cavity over at least a bridging width versus the height-side end of the body corresponding to the closest flexure point section.

Devices, systems, and methods for determining whether a container is empty in the context of robotic picking solutions. The system includes a plurality of sensors configured to gather container data regarding a container at a first location, wherein the container data includes at least two of weight data related to the container, depth data related to the container, and color sensor data related to the container, and a processor configured to execute instructions stored on a memory to provide a sensor fusion module configured to process the received container data to determine whether the container is empty.

A scale controller system and method of using the system is disclosed. The scale controller is adapted for use with a grain cart or similar implement that includes a discharge opening and conveyor. The system includes a scale and a plurality of sensors that work together to automate numerous functions that are typically performed manually. For example, the present invention discloses a system that automatically records the amount of material loaded or unloaded by continuously monitoring the load on a scale and the RPMs of a power take-off shaft that drives a conveyor.

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.

An article inspection apparatus includes a measuring unit 11 that outputs a measuring signal of weight within a required measurement time from a weight application time, when the weight of an article W is applied, a determination unit 16 that inspects the article W based on the measuring signal, an electromagnetic coil 84 that applies a diagnostic load to the measuring unit 11, and a performance diagnosis unit 18 that causes the diagnostic load to be applied from the electromagnetic coil 84 to the measuring unit 11, within a predetermined diagnosable time longer than the required measurement time from the weight application time, when the weight of the article W is applied to the measuring unit 11, and diagnoses the performance of the measuring unit 11, based on the measuring signal when the diagnostic load is applied.

Method for weighing an object transported on a mover of an electromagnetic conveyor and electromagnetic conveyor. Method includes lifting object off the mover with a lifting device; setting down object onto at least one transport plane of a weighing station arranged at a weighing region of the track and arranged on at least one weigh cell. The transport plane extends in the direction of movement to support the object when in the weighing station. The method also includes actively driving object while lifted off from the mover and while supported on the transport plane with the mover as it moves along the track through a weighing region; weighing object with at least one weigh cell while the object is supported by the transport plane; and setting down object on the mover after weighing in the weighing station for onward movement of object along the track with the mover.

A conveyor belt unit (100) has a configuration-changing mechanism useful for switching between a ready-to-operate configuration and a not-ready-to-operate configuration. A specific embodiment uses a rotating joint element (150) with a thin material bridge (152) that defines a rotary axis. Used with a dynamic checkweigher, the conveyor belt unit has a carrier frame (110) and a belt body (130) connected to it. Rollers (132, 134) are arranged at the ends in transport direction (T) and contrary to the transport direction, with a conveyor belt (136) tensioned across the conveyor rollers. A motor drives the conveyor belt (136) by means of one of the rollers (132, 134). The configuration-changing mechanism is effective between the belt body and the carrier frame.

A weight checker includes a transport unit, a weighing unit, a body, and a frame. The transport unit transports products under inspection. The weighing unit determines the weights of the products under inspection on the transport unit. The body has a screen relating to the weighing performed by the weighing unit. The frame anchors the transport unit and the weighing unit. The frame has rail members that extend in a transport direction of the transport unit. The body is independent of the transport unit and the weighing unit and is mounted to the rail members such that its position in the transport direction TD can be changed.

The present invention relates to a belt conveyor with a weighing device for a dough line, comprising a conveyor device, comprising a frame, at least two rollers supported by the frame, a conveyor belt, arranged movable in a length direction of the belt around the at least two rollers and a slot, extending in a width direction of the conveyor belt, and arranged adjacent to an inwardly facing part of the conveyor belt, and a weighing device, comprising a housing fitting the slot; and being movable into and removable from the slot at least one weighing unit, carried by the housing and arranged with a weighing surface thereof facing outwardly for weighing a weight exercised on the weighing surface.

A belt conveyor conveys discrete articles. The belt conveyor includes: a conveyor frame having a top side, a bottom side, and a length extending in the conveying direction for the discrete articles; a conveying belt configured to revolve around the conveyor frame during operation of the belt conveyor; and a belt-guide mounted to the bottom side of the conveyor frame between the conveyor frame and the conveying belt. The belt-guide includes at least two rolling-element bearings. The inner races of the rolling-element bearings are respectively mounted on axles. The axles are parallel to each other and stationary relative to the conveyor frame. The outer races of the rolling-element bearings have direct contact with the conveying belt.