A cellular wheel sluice for granulate bulk product has a housing in which a cellular wheel is rotatably mounted. The housing has an inlet duct for the bulk product. At least two raised granulate roofs are arranged at the inlet duct. A granulate groove is arranged respectively at the transition between two granulate roofs and/or at the transition between one granulate roof and an inlet edge. The two granulate grooves in each case run together at an intersection point in the rotation direction of the cellular wheel.

A disclosed food processing assembly includes a plurality of food processing units. Each unit is configured to convey food product arriving at an ingress point to an egress point. The assembly includes rotary valves configured to transfer food product from the egress point of one unit to the ingress point of a subsequent unit while maintaining environmental isolation between the two units. A programmable electronic controller is configured to monitor environmental parameters within each unit and to generate control signals provided to various resources to maintain environmental parameters within each unit at a distinct set of value. The resources may include air compressors, steam generators, vacuum pumps, and the like. In this manner, the assembly enables a multi-step food process to proceed essentially continuously with little or no delay between sequential process steps despite with each step being associated with a distinct set of time, temperature, pressure, and humidity values.

A rotary feeder having a stationary, cylindrical housing having disposed therein a number of injection nozzles, and within which rotate a plurality of vanes about a central axis, wherein pairs of adjacent vanes of the plurality of vanes define wedge volumes, wherein the housing extends a width along the central axis, wherein each of the vanes has a length along the central axis, and wherein the injection nozzles are positioned across the width of the housing, such that a spray pattern of a gas injected via the number of injection nozzles spans substantially the entire length of the vanes.

A rotary feeder comprising a stationary, cylindrical housing having disposed therein a number of injection nozzles, and within which rotate a plurality of vanes about a central axis, wherein the housing extends a width along the central axis, wherein each of the vanes has a length along the central axis, and wherein the injection nozzles are positioned across the width of the housing, such that a spray pattern of a gas injected via the number of injection nozzles spans substantially the entire length of the vanes. A system comprising and a method utilizing such a rotary feeder are also provided herein.

A valve comprising a rotor, the rotor comprising two passageways and two or more sealing faces. The valve allowing for controlling air flow between four directions. The valve can be capable of operating in a number of operation modes depending on a position of the rotor. The valve design can include a valve-housing with three ports in plane with a first plane and one port normal to the first plane. A rotary valve provides a plurality of predetermined flow modes between four ports. The valve comprises an outer layer and a rotatable inner layer. The inner layer allows for a number of different flow configurations between four ports.

A fastening system having a supporting strip, to which is fastened, outside the housing of the rotary feeder, a seal designed to seal the blade of the rotor in relation to the housing. The mounted unit of supporting strip and seal is inserted into a groove devised in the blade. This installation unit is then secured to the blade by means of securing screws. The seal can be made from a hard seal, especially steel, or a soft seal, especially rubberized textile, attached on the outside by a locating strip.

The present invention is directed to an applicator having an agricultural product conveying system which transfers particulate material from one or more source containers to application equipment on demand, and meters the material at the application equipment. The conveying system includes an inline metering system including a number of metering devices associated with each compartment of a particulate material tank on the applicator to meter the particulate material disposed within each compartment. The individual metering devices include gates to initially enable the particulate material from a compartment to enter the metering device, and a rotary metering shaft to meter the flow of the particulate material into the conduits while limiting the passage of pressurized air through the metering device and into the compartment. The individual metering devices also include individual motors to control the operation of the metering devices independently from one another that can allow with sectional control and turning compensation.

According to an aspect of the invention, a rotary feeder for transferring comminuted fibrous material is provided having as components: a rotary feeder housing, having at least one inlet opening for receiving material (chips) and at least one opening for discharging material (chips), and an internal shear edge assembly adjacent the inlet; wherein a protective baffle (doctor blade) is adjacent to the shear edge assembly; a rotor, rotatably mounted with the rotary feeder housing and having pockets for accepting material introduced to the rotary feeder housing; and a power source which rotates the rotor in said housing; and wherein the rotary feeder housing has a recess along the length of the rotor in the inlet at an exit end of the inlet, the recess being of sufficient size to allow the shear edge assembly and doctor blade to sit within the recess.

In one embodiment, a pneumatic distribution system configured to distribute a granular product to an agricultural implement includes a first pressure sensor, a second pressure sensor, and a controller. The first pressure sensor is configured to be fluidly coupled to a storage tank configured to store the granular product and positioned upstream of the meter roller. The first pressure sensor is configured to output a first signal indicative of a first static pressure in the storage tank. The second pressure sensor is configured to be fluidly coupled to a component of the pneumatic distribution system, downstream of the meter roller. The second pressure sensor is configured to output a second signal indicative of a second static pressure downstream of the meter roller. The controller is communicatively coupled to the first pressure sensor and to the second pressure sensor. The controller is configured to determine a pressure differential, wherein the pressure differential is the difference between the first static pressure and the second static pressure. The controller may also be configured to generate a first warning when the first static pressure is below a threshold value and output the first warning to an operator interface, generate a second warning when the pressure differential is below a desired range and output the second warning to the operator interface, and generate a third warning when the pressure differential is above the desired range and output the third warning to the operator interface.

A method of manufacturing a meter roller for an agricultural metering system includes stretching a sealing ring. The method also includes disposing the sealing ring between a first ring of a spindle and a second ring of the spindle. The first ring and the second ring are rigidly coupled to a driven shaft of the spindle, and the driven shaft is configured to engage a drive shaft to facilitate rotation of the spindle. In addition, the method includes enabling the sealing ring to contract such that an outer diameter of the sealing ring is less than or equal to an outer diameter of the first ring and an outer diameter of the second ring.