A close tolerance disc for a flexible member conveyor including a disc body member and a movable resilient ring. The ring is preferably formed of a durable polymer interlocking ring where the ring outer periphery closely matches the inside surface of the conveyor tubing. The resilience of the ring biases it to conform to the inside surface of the conveyor tubing to provide 100% conveyance of the material in the system. The ring can move in place within a groove in the body member of the disc, as well as distort to self-align and conform to the irregularities that are present in the manufacturing of the conveyor tubular components. The ring is easily removeable for quick replacement and cleaning. The interlocking ends of the ring keep the ring ends in place and in line to prevent the ends from being misaligned while passing through a partially cutaway portion of the tube.

A close tolerance disc for a flexible member conveyor including a disc body member and a movable resilient ring. The ring is preferably formed of a durable polymer interlocking ring where the ring outer periphery closely matches the inside surface of the conveyor tubing. The resilience of the ring biases it to conform to the inside surface of the conveyor tubing to provide 100% conveyance of the material in the system. The ring can move in place within a groove in the body member of the disc, as well as distort to self-align and conform to the irregularities that are present in the manufacturing of the conveyor tubular components. The ring is easily removeable for quick replacement and cleaning. The interlocking ends of the ring keep the ring ends in place and in line to prevent the ends from being misaligned while passing through a partially cutaway portion of the tube.

Systems, feeder devices and methods for moving particulate hot melt adhesive from an adhesive supply to an adhesive melter. A feeder device includes a body having an inlet and an outlet, and an interior communicating with the inlet and the outlet. The inlet is configured to receive particulate hot melt adhesive from an outlet of the adhesive supply, and the outlet is configured to provide particulate hot melt adhesive to an inlet of the adhesive melter. The feeder device further includes a mechanical agitator positioned in the interior for urging the particulate hot melt adhesive in a flow direction toward the outlet.

Systems, feeder devices and methods for moving particulate hot melt adhesive from an adhesive supply to an adhesive melter. A feeder device includes a body having an inlet and an outlet, and an interior communicating with the inlet and the outlet. The inlet is configured to receive particulate hot melt adhesive from an outlet of the adhesive supply, and the outlet is configured to provide particulate hot melt adhesive to an inlet of the adhesive melter. The feeder device further includes a mechanical agitator positioned in the interior for urging the particulate hot melt adhesive in a flow direction toward the outlet.

The present invention relates to a drive station for a device for conveying bulk material, the drive station comprising: - a housing, which has a base plate and side walls, at least one side wall having at least one opening for the passage of a conveying means for conveying the bulk material along a passage path; and — a drive for moving the conveying means, the drive being disposed in the housing. A preferably movable intermediate base having openings is disposed below the passage path and above the base plate in the vertical direction.

The present invention relates to a drive station for a device for conveying bulk material, the drive station comprising: - a housing, which has a base plate and side walls, at least one side wall having at least one opening for the passage of a conveying means for conveying the bulk material along a passage path; and — a drive for moving the conveying means, the drive being disposed in the housing. A preferably movable intermediate base having openings is disposed below the passage path and above the base plate in the vertical direction.

A traction mechanism for pipeline conveying apparatus comprises a flat belt and a plurality of trays fixedly arranged in the lengthwise direction at intervals on the flat belt. The pipeline conveying apparatus further comprises a pipeline, where the traction mechanism is arranged in the pipeline in a penetrating manner, and the pipeline conveying apparatus is further provided with a driving mechanism for driving the traction mechanism to move in the pipeline.

A traction mechanism for pipeline conveying apparatus comprises a flat belt and a plurality of trays fixedly arranged in the lengthwise direction at intervals on the flat belt. The pipeline conveying apparatus further comprises a pipeline, where the traction mechanism is arranged in the pipeline in a penetrating manner, and the pipeline conveying apparatus is further provided with a driving mechanism for driving the traction mechanism to move in the pipeline.

An in-line valve assembly for a tubular drag conveyer system includes a first tube segment having a first end and defining a first passageway, a second tube segment having a second end and defining a second passageway, and a tubular valve body translatably disposed relative to the second tube segment and defining a valve passageway. The first end of the first tube segment is spaced apart from the second end of the second tube segment by a gap. The valve body is selectively adjustable between a closed position wherein the valve passageway spans the gap and connects the first passageway to the second passageway and an open position wherein the valve passageway is spaced apart from the first passageway by at least a portion of the gap.

An in-line valve assembly for a tubular drag conveyer system includes a first tube segment having a first end and defining a first passageway, a second tube segment having a second end and defining a second passageway, and a tubular valve body translatably disposed relative to the second tube segment and defining a valve passageway. The first end of the first tube segment is spaced apart from the second end of the second tube segment by a gap. The valve body is selectively adjustable between a closed position wherein the valve passageway spans the gap and connects the first passageway to the second passageway and an open position wherein the valve passageway is spaced apart from the first passageway by at least a portion of the gap.