A flow splitter includes a body having a generally cylindrical main passage therethrough oriented along a longitudinal axis of the body. The main passage connects an inlet at the upstream end to exactly three split passages adjacent the downstream end, each split passage connected to a corresponding outlet. A first and second of the three split passages are oriented along axes that intersect one another at a first acute angle in a common plane with the longitudinal axis. A third of the three split passages intersects the common plane at a second acute angle. An agricultural implement includes a frame, a toolbar carried by the frame and supporting a plurality of row units, a hopper carried by the frame, a primary flow line connecting the hopper to a flow splitter, and three secondary flow lines connecting the flow splitter to three of the row units.

A flow splitter distributes solid particles flowing in a fluid, such as coal particles flowing in air, through a piping system. The flow splitter includes a divider housing having an inlet configured to connect to an upstream pipe and having an outlet configured to connect to a plurality of downstream pipes, e.g., by way of a divider head. A divider body is mounted within the divider housing. A plurality of divider vanes is included, each extending from the divider body to the divider housing. The divider housing, divider body, and divider vanes are configured and adapted to reduce non-uniformity in particle concentration from the inlet and to supply a substantially equal particle flow from the outlet to each of the downstream pipes.

A material handling system includes a chassis, a conveyor system supported by the chassis, a pneumatic conveying system supported by the chassis and a storage container supported by the chassis. The conveyor system is configured to convey a granular material from a material unloading station to an inlet of the storage container. Multiple pods are beneath the storage container. Each pod is connected to the storage container by a corresponding pod fill line. A pneumatic conveying line is beneath the pods. The pneumatic conveying line is connected to each of the pods. Each pod has a full level sensor configured to sense when the pod is full or close to full, and an empty level sensor configured to sense when the pod is empty or close to empty.

A material handling system includes a chassis, a conveyor system supported by the chassis, a pneumatic conveying system supported by the chassis and a storage container supported by the chassis. The conveyor system is configured to convey a granular material from a material unloading station to an inlet of the storage container. Multiple pods are beneath the storage container. Each pod is connected to the storage container by a corresponding pod fill line. A pneumatic conveying line is beneath the pods. The pneumatic conveying line is connected to each of the pods. Each pod has a full level sensor configured to sense when the pod is full or close to full, and an empty level sensor configured to sense when the pod is empty or close to empty.

A mixture of gas and solid particles are conveyed through a piping circuit connected between initial and terminal points. The gas is introduced at the initial point and the particles are introduced between the initial and terminal points. A diameter of the piping circuit increases downstream of where the particles are introduced, and a velocity of the gas is at least as great as a pick-up velocity of the particles at the point where the particles are introduced into the piping circuit. In addition to the above constraints, the piping circuit is sized so that total pressure losses due to flow in the piping circuit between the initial and terminal points are within a designated amount.

Methods and system for waste collection and transport systems are provided. Systems of the present disclosure comprise at least one of a loading station and a chute providing a point of ingress for materials into a larger system. A plurality of vertical risers or branches are provided. The system and related methods generate a priority order of emptying loading stations based at least in part on loading stations that are provided on the same riser.

A mixture of gas and solid particles are conveyed through a piping circuit connected between initial and terminal points. The gas is introduced at the initial point and the particles are introduced between the initial and terminal points. A diameter of the piping circuit increases downstream of where the particles are introduced, and a velocity of the gas is at least as great as a pick-up velocity of the particles at the point where the particles are introduced into the piping circuit. In addition to the above constraints, the piping circuit is sized so that total pressure losses due to flow in the piping circuit between the initial and terminal points are within a designated amount.

A mixture of gas and solid particles are conveyed through a piping circuit connected between initial and terminal points. The gas is introduced at the initial point and the particles are introduced between the initial and terminal points. A diameter of the piping circuit increases downstream of where the particles are introduced, and a velocity of the gas is at least as great as a pick-up velocity of the particles at the point where the particles are introduced into the piping circuit. In addition to the above constraints, the piping circuit is sized so that total pressure losses due to flow in the piping circuit between the initial and terminal points are within a designated amount.

Methods and system for waste collection and transport systems are provided. Systems of the present disclosure comprise at least one of a loading station and a chute providing a point of ingress for materials into a larger system. A plurality of vertical risers or branches are provided. The system and related methods generate a priority order of emptying loading stations based at least in part on loading stations that are provided on the same riser.

The invention relates to a suction device for emptying a container, in particular for emptying a container filled with granular material. The suction device has a plurality of intakes, at least one distributor, the at least one distributor being adapted to connect the plurality of intakes to a central suction line, and a means for holding, which holds at least one first intake of the plurality of intakes at a distance from at least one second intake of the plurality of intakes. The invention further relates to a method and to a system for emptying a container, in particular for emptying a container filled with granular material.