The present invention relates to a conveying apparatus for tampon applicators 100, having a first conveyor track 2, which comprises two transport belts 3.1, 3.2 which are arranged spaced apart from each other. The transport belts each have a bearing axis L1, L2. The conveying apparatus according to the invention furthermore has a first conveyor drive 4 for driving at least one of the two spaced-apart transport belts 3.1, 3.2, and transport belts which are arranged spaced apart from each other in such a manner that a tampon applicator 100 which is to be conveyed rests on the two transport belts in an intermediate space D between the transport belts. The bearing axes L1, L2 of the transport belts 3.1, 3.2 are arranged parallel; in particular in the case of transport belts having the same conveying direction F. The present invention furthermore relates to a method of conveying tampon applicators.

A conveying apparatus for tampon applicators has a first conveyor track, which includes two transport belts which are arranged spaced apart from each other. The transport belts each have a bearing axis. The conveying apparatus furthermore has a first conveyor drive for driving at least one of the two spaced-apart transport belts, and transport belts which are arranged spaced apart from each other in such a manner that a tampon applicator which is to be conveyed rests on the two transport belts in an intermediate space between the transport belts. The bearing axes of the transport belts are arranged parallel; in particular in the case of transport belts having the same conveying direction. Furthermore, a method conveys tampon applicators.

Disclosed is a transport system for handling a plurality of different types of containers for medical equipment in a sterile processing department, the system comprises: a plurality of containers of a first type and a plurality of containers of a second type; conveyor stations for the plurality of containers, the conveyor stations being configured to transport the first type of containers and/or the second type of containers relative to the conveyor station; and a transport tray for supporting the first type of containers and the second type of containers, the transport tray having a set of securing elements configured to releasably secure the first type of containers to the transport tray and the second type of containers to the transport tray. The conveyor station is configured to transport the first type of containers and/or the second type of containers secured to the transport tray.

Features are disclosed for a stopping device that is resistant to forces in a first direction and compliant with forces in a second direction. The stopping device may be implemented in a roller top to restrict undesired horizontal movement of a payload being transported across the roller top. In some embodiments, the roller top can be implemented on a mobile robot to transport a payload between destinations. The stopping device can include a plurality of linkages to engage the stopping device and reduce forces applied to the stopping device by the payload. The stopping device, in an engaged position, may limit undesired horizontal movement of the payload. Further, the stopping device, in the engaged position, may respond to vertical forces applied to the stopping device by transitioning from the engaged position to a disengaged position.

Disclosed is a transport system for handling a plurality of different types of containers for medical equipment in a sterile processing department, the system comprises: a plurality of containers of a first type and a plurality of containers of a second type; a conveyor stations for the plurality of containers, the conveyor stations being configured to transport the first type of containers and/or the second type of containers relative to the conveyor station; and a transport tray for supporting the first type of containers and the second type of containers, the transport tray having a set of securing elements configured to releasably secure the first type of containers to the transport tray and the second type of containers to the transport tray. The conveyor station is configured to transport the first type of containers and/or the second type of containers secured to the transport tray.

The present invention relates to a conveying apparatus for tampon applicators 100, having a first conveyor track 2, which comprises two transport belts 3.1, 3.2 which are arranged spaced apart from each other. The transport belts each have a bearing axis L1, L2. The conveying apparatus according to the invention furthermore has a first conveyor drive 4 for driving at least one of the two spaced-apart transport belts 3.1, 3.2, and transport belts which are arranged spaced apart from each other in such a manner that a tampon applicator 100 which is to be conveyed rests on the two transport belts in an intermediate space D between the transport belts. The bearing axes L1, L2 of the transport belts 3.1, 3.2 are arranged parallel; in particular in the case of transport belts having the same conveying direction F. The present invention furthermore relates to a method of conveying tampon applicators.

Features are disclosed for a stopping device that is resistant to forces in a first direction and compliant with forces in a second direction. The stopping device may be implemented in a roller top to restrict undesired horizontal movement of a payload being transported across the roller top. In some embodiments, the roller top can be implemented on a mobile robot to transport a payload between destinations. The stopping device can include a plurality of linkages to engage the stopping device and reduce forces applied to the stopping device by the payload. The stopping device, in an engaged position, may limit undesired horizontal movement of the payload. Further, the stopping device, in the engaged position, may respond to vertical forces applied to the stopping device by transitioning from the engaged position to a disengaged position.

Embodiments provide an electric lug loader system. An electric lug loader may include a shaft assembly rotatably mounted to a frame that extends across a flow path. The shaft assembly may have shafts arranged radially around, and parallel to, the rotational axis of the shaft assembly, clamp members arranged along each of the shafts, support members arranged radially around the rotational axis and across the flow path, and electric drives coupled to the shafts. Conveyors may be coupled with the frame and spaced apart across the flow path upstream and/or downstream of the shaft assembly. Additional drives may be coupled with the shaft assembly and the conveyors. A controller may be configured to synchronize the drives to engage successive workpieces between the clamp members and the support members and deposit the workpieces onto a lugged conveyor. Other embodiments provide related methods and systems.

Embodiments provide an electric lug loader system. An electric lug loader may include a shaft assembly rotatably mounted to a frame that extends across a flow path. The shaft assembly may have shafts arranged radially around, and parallel to, the rotational axis of the shaft assembly, clamp members arranged along each of the shafts, support members arranged radially around the rotational axis and across the flow path, and electric drives coupled to the shafts. Conveyors may be coupled with the frame and spaced apart across the flow path upstream and/or downstream of the shaft assembly. Additional drives may be coupled with the shaft assembly and the conveyors. A controller may be configured to synchronize the drives to engage successive workpieces between the clamp members and the support members and deposit the workpieces onto a lugged conveyor. Other embodiments provide related methods and systems.

Embodiments provide an electric lug loader system. An electric lug loader may include a shaft assembly rotatably mounted to a frame that extends across a flow path. The shaft assembly may have shafts arranged radially around, and parallel to, the rotational axis of the shaft assembly, clamp members arranged along each of the shafts, support members arranged radially around the rotational axis and across the flow path, and electric drives coupled to the shafts. Conveyors may be coupled with the frame and spaced apart across the flow path upstream and/or downstream of the shaft assembly. Additional drives may be coupled with the shaft assembly and the conveyors. A controller may be configured to synchronize the drives to engage successive workpieces between the clamp members and the support members and deposit the workpieces onto a lugged conveyor. Other embodiments provide related methods and systems.