An assembly line grow pod includes a seeding region, a harvesting region, a track that extends between the seeding region and the harvesting region, a cart including a tray for holding plant matter, and a wheel coupled to the tray, where the wheel is engaged with the track, and a weight sensor positioned on the cart or the track, where the weight sensor is positioned to detect a weight of the plant matter positioned within the cart.

A product inspection apparatus includes a conveyor system for transporting items. The conveyor system includes a weigh conveyor with a load detector for detecting the weight of items transported on the conveyor system and a transport conveyor adjacent the weigh conveyor. The apparatus also includes a support structure with a support beam. The transport conveyor is mounted to the support beam by at least one support column externally mounted to the support beam such that vibrations are suppressed by the at least one externally mounted support column.

A crop elevator for a combine harvester includes an ascending section and a descending section and a housing enclosing the ascending section and the descending section. The elevator further comprises an elevator loop arranged inside the housing which includes a plurality of paddles for elevating a harvested crop. The elevator also includes a weighing system configured to determine a weight of harvested crop that is present on at least one of the paddles during an ascending movement of the at least one of the paddles in the ascending section. The weighing system includes a weight sensor configured to output a weight signal representative of the weight of the harvested crop. The ascending section of the elevator comprises a measurement section, wherein the weighing system is configured to retrieve the weight signal when the at least one of the paddles is in the measurement section of the elevator.

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.

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.

In a method and apparatus for length measurement of a flat good in a goods processing system having first and second stations, each having a sensor in the transport direction of the flat good, a control processor implements a path control and counts encoder pulses of an encoder in the first station. An event is determined by the sensor of the second station, and an associated numerical value Z1 of the encoder pulses is stored in the control processor, as is a numerical value Z2 for a distance between the two sensors is also stored. An additional event is determined by the sensor of the first station, and an associated numerical value Z3 of the encoder pulses is stored. As soon as both events are present, Z2 and the difference Δ=Z3−Z1 are added by the control processor, and the sum is used to designate the length.

A weighing system for weighing an item when being conveyed comprising: at least one container for transporting the item; a conveyor means for conveying said container in a first vertical direction; and a weighing device for weighing the container;
wherein the container is connected to the conveyor means via a primary connecting means and a secondary connecting means, each of them comprising a first section permanently connected to the container, a second section permanently connected to the conveyor means, and a third section hingedly connected to both the first section and the second section;
and wherein the third section of the primary connecting means is rotatable about a first axis transverse to the conveying direction and the third section of the secondary connecting means is rotatable about a second axis parallel to said conveying direction such that the container may move from the first vertical position to a second vertical position.

A conveyor and metering device having a continuous conveyor belt or conveyor band, sub-regions of this conveyor belt or conveyor band being mounted on weighing devices for determining the mass of the conveyed material, which are connected to an electronic evaluation device, the weighing devices generating a signal proportional to the load of the conveyor belt or conveyor band and transmitting it to the evaluation device, weighing devices are provided, each of which includes a bearing bracket, which is used to receive an attachment in a form-filling manner from the outside, preferably from above, through an opening in the frame of the conveyor and metering device during the operation of the conveyor.

A weigh belt assembly includes a weigh belt that has first and second spaced apart rollers and an endless belt trained around the rollers to present a belt run configured to support particulate material. The rollers each have a rotational axis. The assembly also includes a belt drive operably coupled with at least one of the rollers for rotation thereof in order to move the belt run in a direction toward the second roller. The assembly also includes apparatus for delivery of quantities of particulate material onto the moving belt run at a position between the first and second rollers. The assembly further comprises a pivot assembly including a shiftable component operably coupled with the weigh belt in order to permit pivoting and downward deflection of the weigh belt under the load of the particulate material deposited on the belt run. A device for measuring the load experienced by the weigh belt during the deflection thereof is provided. A method of determining the flow rate of a particulate material and/or the total weight of material delivered using a weigh belt is also disclosed.

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.