A transfer element for being arranged between a dosing device and the filling device of a tubular bag machine, the dosing device allowing for the dosing of a prespecified filling quantity of the filling material to be filled into a tubular bag, and the transfer element comprising at least one input station, at least one dispensing station and several transfer containers, and a prespecified filling quantity of a filling material being transferable from the dosing device to the transfer containers in the input station, and the transfer containers being transported to the dispensing station along a transfer line, and the filling material being transferable from the transfer containers to the filling device in the dispensing station, and the transfer containers being transported back to the input station along a return transfer line, the transfer element being controlled by a transfer control system, the transfer control system controlling the transfer process for transferring the filling material from a transfer container to the filling device of the tubular bag machine in the dispensing station a) in accordance with the position of the transfer container relative to the filling device and/or b) in accordance with the speed of the transfer container.

A transfer element for being arranged between a dosing device and the filling device of a tubular bag machine, the dosing device allowing for the dosing of a prespecified filling quantity of the filling material to be filled into a tubular bag, and the transfer element comprising at least one input station, at least one dispensing station and several transfer containers, and a prespecified filling quantity of a filling material being transferable from the dosing device to the transfer containers in the input station, and the transfer containers being transported to the dispensing station along a transfer line, and the filling material being transferable from the transfer containers to the filling device in the dispensing station, and the transfer containers being transported back to the input station along a return transfer line, the transfer element being controlled by a transfer control system, the transfer control system controlling the transfer process for transferring the filling material from a transfer container to the filling device of the tubular bag machine in the dispensing station a) in accordance with the position of the transfer container relative to the filling device and/or b) in accordance with the speed of the transfer container.

The present disclosure provides a peanut whole-process production line and a method. The peanut whole-process production line includes a peanut cleaning system, a shell breaking system, a skin removing system, a peanut kernel classification system, an ultra-fine pulverization system and a classification packaging system; a first procedure is cleaning and impurity removal of peanuts, breaking of peanut shells is performed after the cleaning and impurity removal of peanuts, removal of peanut kernel skins and ultra-fine pulverization of the peanut shells are respectively performed after the breaking of peanut shells, classification of peanut kernels is performed after the removal of peanut kernel skins, and classification packaging of ultra-fine peanut shell powder is performed after the ultra-fine pulverization of the peanut shells; whole-process processing of peanuts is completed by using the peanut whole-process production line, and peanut resources are fully utilized.

The present disclosure provides a peanut whole-process production line and a method. The peanut whole-process production line includes a peanut cleaning system, a shell breaking system, a skin removing system, a peanut kernel classification system, an ultra-fine pulverization system and a classification packaging system; a first procedure is cleaning and impurity removal of peanuts, breaking of peanut shells is performed after the cleaning and impurity removal of peanuts, removal of peanut kernel skins and ultra-fine pulverization of the peanut shells are respectively performed after the breaking of peanut shells, classification of peanut kernels is performed after the removal of peanut kernel skins, and classification packaging of ultra-fine peanut shell powder is performed after the ultra-fine pulverization of the peanut shells; whole-process processing of peanuts is completed by using the peanut whole-process production line, and peanut resources are fully utilized.

A sandbag filling system includes a support frame, a driving unit, a conveyor unit, and a hopper chute. The support frame includes a feed gate and an adjustable mount and is configured to receive a material and guide the material to a conveyor belt. The driving unit is arranged in the support frame and includes a motor connected to a drive shaft. The conveyor unit is arranged in the support frame as well and includes a conveyor belt configured to be moved by the driving unit. The hopper chute is arranged below the feed gate of the support frame and located proximal to the conveyor belt.

A sandbag filling system includes a support frame, a driving unit, a conveyor unit, and a hopper chute. The support frame includes a feed gate and an adjustable mount and is configured to receive a material and guide the material to a conveyor belt. The driving unit is arranged in the support frame and includes a motor connected to a drive shaft. The conveyor unit is arranged in the support frame as well and includes a conveyor belt configured to be moved by the driving unit. The hopper chute is arranged below the feed gate of the support frame and located proximal to the conveyor belt.

A rotary filling machine for filling containers with bridgeable dry materials includes a turret supporting a plurality of circumferentially spaced drop buckets and a plurality of funnel assemblies located under the drop buckets. A stationary slide plate is located vertically between the funnel assemblies and the drop buckets. The slide plate is configured such that flow paths from the bottoms of the drop buckets to the inlet openings of the funnel assemblies increase progressively in at least a portion of a circumferential extent of the slide plate. Drop buckets are located above the slide plate and rotate with the turret. Each drop bucket is provided with one or more partitions that hinder the “snow-plowing of particles” along the edge of the associated fill opening in the machine’s fill plate rather than the sweeping of those particles into the fill opening.

A rotary filling machine for filling containers with bridgeable dry materials includes a turret supporting a plurality of circumferentially spaced drop buckets and a plurality of funnel assemblies located under the drop buckets. A stationary slide plate is located vertically between the funnel assemblies and the drop buckets. The slide plate is configured such that flow paths from the bottoms of the drop buckets to the inlet openings of the funnel assemblies increase progressively in at least a portion of a circumferential extent of the slide plate. Drop buckets are located above the slide plate and rotate with the turret. Each drop bucket is provided with one or more partitions that hinder the “snow-plowing of particles” along the edge of the associated fill opening in the machine’s fill plate rather than the sweeping of those particles into the fill opening.

A powder filling method includes introducing a tube into a can so that the lower end of the tube is near the bottom of the can. The powder in the can is introduced through the tube. The proximity of the lower end of the tube to the powder is controlled by retracting the tube as the powder fills the can.

A powder filling method includes introducing a tube into a can so that the lower end of the tube is near the bottom of the can. The powder in the can is introduced through the tube. The proximity of the lower end of the tube to the powder is controlled by retracting the tube as the powder fills the can.