The present disclosure generally relates to systems and methods utilizing regenerative agriculture for the procurement, production, refinement and/or transformation of low carbon intensity transportation fuels, including low carbon intensity biodiesel and/or renewable diesel, low carbon intensity biogasoline, low carbon intensity aviation, marine and kerosene fuels as well as fuel oil blends, low carbon intensity ethanol, and low carbon intensity hydrogen, that may be beneficially commercialized directly to consumers. In further aspects, the systems and methods of the present disclosure advantageously generate low carbon intensity comestibles, including sustainably-sourced meal and/or feed. The disclosed systems and methods may be utilized and optimized such that the resulting fuels and foodstuffs are characterized by a reduction in greenhouse gas production and a diminution in the fertilizer, pesticide and water required for producing the associated crop feedstocks.

An industrial facility monitoring system may include a matrix of radiofrequency (RF) mesh extenders and a processing unit. Each of the RF mesh extenders is fixed to building structures of a facility and located throughout an interior of the facility. Each of the RF mesh extenders is to receive signals from RF emitters coupled to facility occupants. The processing unit receives signals from the RF mesh extenders and determines coordinates of a facility occupant based upon a triangulation of the signals from the matrix of RF mesh extenders.

A system and method for controlling movement of transporting devices arranged to transport containers, the containers being stored in stacks arranged in a facility. A facility having pathways arranged in a grid-like structure above stacks, the transporting devices being configured to operate on the grid-like structure. A control unit configured to determine at least one task to be performed by at least one transporting device, wherein the at least one task is determined based on at least one of: transporting device battery condition, transporting device damage, transporting device maintenance issues, and transporting device service issues.

In a first step of a method for bundling conveying streams on a material handling element including a number of incoming conveyor segments, at least one coupling to an outgoing conveyor segment, on which the incoming conveyor segments converge, and a number of holding devices for holding a conveying stream on the incoming conveyor segments, target arrival times, at which the objects arrive as planned at a destination, are calculated for the conveyed objects. A conveyed object is released at a release time which substantially corresponds to the target arrival time minus the target pass-through time required for the conveyed object to be transported as planned from a current position to the destination. A material handling element carries out the method.

Manufacturing of article of footwear include temporarily mating a sole and an upper to determine processes to be performed to the sole and/or the upper before permanently mating. As specific operations are determined based on the particular combination of a sole and an upper, the sole and upper are individually tracked through the subsequent processes to ensure the correct pairing is achieved at the time of permanent mating. The tracking may leverage identifiers in the tooling supporting the upper and in the sole.

Various embodiments described herein relate to controlling a conveyor that comprises at least a first zone that is upstream of a second zone. A second control module associated with the second zone receives a first signal from a first control module associated with the first zone.

The first signal indicates that one of a first article that has an irregular boundary or a second article that has a regular boundary exits from the first zone. The second control module controls the second drive assembly and a second brake assembly based on the indication by the first signal.

The present invention increases the productivity of an entire factory, even of the type that produces different types of products in different quantities using transport vehicles, by performing transport operation control. This transport operation control device is provided with: a spatial distribution measuring unit which measures the spatial distribution of products-in-process being transported by the transport vehicles; and an operation schedule calculation unit which, on the basis of the measured spatial distribution of the group of partly-finished products, calculates an operation schedule that specifies both a route and a frequency of a transport operation to be carried out by each transport vehicle of the transport vehicles, wherein the operation schedule calculation unit determines the timing with which to update the operation schedule, on the basis of changes in a productivity index that is determined from the measured spatial distribution of the products-in-process.

A working system includes multiple modules constituting a work line, a moving body that moves along the work line in which the multiple modules are arranged to supply necessary members to each module, and a line constituent member constituting a part of the work line. The line constituent member can be installed on the moving path of the moving body and has a light projecting section that projects light toward the moving body along the moving path of the moving body. The moving body has a sensor configured to detect the presence of an interfering object; a light receiving section configured to receive light from the light projecting section, and a control section configured to monitor for the presence of the interfering object within a detection range of the sensor.

A substrate processing apparatus includes: a stage configured to place thereon a substrate or at least a portion of a substrate holding member configured to hold the substrate, the substrate having two sides extending in a first direction and two sides extending in a second direction; a transporter configured to transport the substrate to a position facing the stage; first and second sensors, which are fixed relative to the stage and respectively located outside the sides, extending in the second direction, of the substrate at the position facing the stage so as to detect the sides of the substrate, respectively; and third and fourth sensors, which are fixed relative to the stage and respectively located outside the sides, extending in the first direction, of the substrate at the position facing the stage so as to detect the sides of the substrate, respectively.

A dispatch system and a dispatch method for manufacturing mold are provided. The dispatch system includes a control unit, a mold material storage unit, a processing cutter storage unit, an object pick-and-place and transfer unit, a mold processing unit and a mold product storage unit. The mold material storage unit includes many unprocessed mold materials. The processing cutter storage unit includes many processing cutters. The object pick-and-place and transfer unit is electrically connected to the control unit and disposed between the mold material storage unit and the processing cutter storage unit. One of the unprocessed mold materials and one of the processing cutters are transferred to the mold processing unit by the object pick-and-place and transfer unit, the unprocessed mold material is processed to form a mold product by the mold processing unit, and the mold product is transferred to the mold product storage unit.