A system is disclosed for controlling the disgorging of objects. The system includes a container system including a container for containing objects, rotation means for rotating the container to a disgorgement angle, and movement means for moving at least a portion of the container system in a repetitious manner with a net zero distance of travel of the at least the portion of the container system such that the objects are disgorged from the container at a controlled rate of disgorgement.

A system is disclosed for controlling the disgorging of objects. The system includes a container system including a container for containing objects, rotation means for rotating the container to a disgorgement angle, and movement means for moving at least a portion of the container system in a repetitious manner with a net zero distance of travel of the at least the portion of the container system such that the objects are disgorged from the container at a controlled rate of disgorgement.

A taco stacking apparatus comprises a conveyor assembly for supporting and moving taco shells along a predefined pathway. The conveyor assembly defines an opening in the predefined pathway that enables the taco shells to pass through the conveyor assembly. A stacking receptacle defines a channel for receiving taco shells passed through the opening in the predefined pathway of the conveyor assembly. A plunger assembly passes a taco shell through the opening in the predefined pathway of the conveyor assembly to the stacking receptacle.

Embodiments include a parcel processing system and methods for operating the same. The parcel processing system includes a collector configured to receive a flow of parcels and a slug accumulation system configured to receive the flow of parcels and produce a normalized bulk flow of parcels. The parcel processing system also includes a bulk transport conveyor configured to receive the normalized bulk flow of parcels and a singulator configured to receive the normalized bulk flow of parcels from the bulk transport conveyor. The normalized bulk flow of parcels is a flow of parcels having an approximately constant parcel density traveling at a fixed speed.

Embodiments include a parcel processing system and methods for operating the same. The parcel processing system includes a collector configured to receive a flow of parcels and a slug accumulation system configured to receive the flow of parcels and produce a normalized bulk flow of parcels. The parcel processing system also includes a bulk transport conveyor configured to receive the normalized bulk flow of parcels and a singulator configured to receive the normalized bulk flow of parcels from the bulk transport conveyor. The normalized bulk flow of parcels is a flow of parcels having an approximately constant parcel density traveling at a fixed speed.

The disclosure relates to a method for inserting products into trays at a loading station for a tray sealer, where a tray of several trays loaded with product by way of a gripper unit to a target value at the loading station and provided therein on a tray conveyor is pushed directly onto a discharge belt of the loading station by way of a tray pusher formed on the gripper unit. The disclosure furthermore relates to a loading station for a tray sealer.

A rejection device includes a detection sensor that detects an article, pressurization point setting means for setting an essential pressurization point of the article by using a distance from a front end of the article and a transport time corresponding to a transport speed for each type of the article by a compressed air, a management timer that manages a rejection delay time set by using a delay time from a detection time point when a rear end of the article is detected by a detection sensor to a time point when the essential pressurization point enters a discharge bias section, and rejection command means for inputting a rejection command signal to the rejection unit for a predetermined command time from a time-up time point of the management timer.

A rejection device includes a detection sensor that detects an article, pressurization point setting means for setting an essential pressurization point of the article by using a distance from a front end of the article and a transport time corresponding to a transport speed for each type of the article by a compressed air, a management timer that manages a rejection delay time set by using a delay time from a detection time point when a rear end of the article is detected by a detection sensor to a time point when the essential pressurization point enters a discharge bias section, and rejection command means for inputting a rejection command signal to the rejection unit for a predetermined command time from a time-up time point of the management timer.

A system for inspecting bottles includes a conveyor conveying bottles at a first speed. A starwheel, rotating at a second speed, less than the first speed, receives each bottle. Sensors are disposed adjacent the starwheel for detecting at least one of a residual liquid in the bottle and a defect in the bottle. The starwheel deposits each bottle on the conveyor at a downstream position. An outer sidewall inspection system, disposed along the path, has a first camera assembly and a second camera assembly disposed along the path and each bottle passes therebetween. A first belt is disposed along the conveyor in facing relation with a second belt to rotate the bottle. The outer sidewall inspection system has a third camera assembly and a fourth camera assembly disposed along the path, downstream of the first belt; each bottle passing between the third camera assembly and the fourth camera assembly.

A system for inspecting bottles includes a conveyor conveying bottles at a first speed. A starwheel, rotating at a second speed, less than the first speed, receives each bottle. Sensors are disposed adjacent the starwheel for detecting at least one of a residual liquid in the bottle and a defect in the bottle. The starwheel deposits each bottle on the conveyor at a downstream position. An outer sidewall inspection system, disposed along the path, has a first camera assembly and a second camera assembly disposed along the path and each bottle passes therebetween. A first belt is disposed along the conveyor in facing relation with a second belt to rotate the bottle. The outer sidewall inspection system has a third camera assembly and a fourth camera assembly disposed along the path, downstream of the first belt; each bottle passing between the third camera assembly and the fourth camera assembly.