A loading-dock signaling system includes an internal signal light, an external signal light and a wheel chock having a base and a handle extending from the base. A chock signal light is positioned on the handle. The internal signal light, the external signal light and the chock signal light are in signal communication with one another to provide at least a plurality of illuminated indicia to an exterior dock area and an interior dock area. The exterior dock area and the interior dock area are separated by a dock door.

A conveyor system for moving a plurality of targets is provided. The conveyor system includes at least one input group to input the target, at least one output group to output the target, and at least one bridge group to connect the input group with the output group. Each of the input group, the output group, and the bridge group includes a plurality of nodes having a size corresponding to a size of one target. The conveyor system further includes a control unit to align the target moving on the conveyor system.

A conveyor system for moving a plurality of targets is provided. The conveyor system includes at least one input group to input the target, at least one output group to output the target, and at least one bridge group to connect the input group with the output group. Each of the input group, the output group, and the bridge group includes a plurality of nodes having a size corresponding to a size of one target. The conveyor system further includes a control unit to align the target moving on the conveyor system.

Embodiments provide for systems and methods related to kiosks for personalizing a packaged article. The kiosks may also be used for storage, inventory management, retrieval, packaging, and/or personalization of packaged articles. The kiosks discussed herein differ from non-kiosk personalization systems, such as personalization systems installed on a factory or warehouse floor, in that the kiosks are self-contained personalization systems. In some embodiments, the kiosks are portable and can be moved between different sites or events. This portability allows the kiosks to personalize packaged articles for concerts, festivals, conventions, trade shows, and the like.

Embodiments provide for systems and methods related to kiosks for personalizing a packaged article. The kiosks may also be used for storage, inventory management, retrieval, packaging, and/or personalization of packaged articles. The kiosks discussed herein differ from non-kiosk personalization systems, such as personalization systems installed on a factory or warehouse floor, in that the kiosks are self-contained personalization systems. In some embodiments, the kiosks are portable and can be moved between different sites or events. This portability allows the kiosks to personalize packaged articles for concerts, festivals, conventions, trade shows, and the like.

A dock apparatus includes a plurality of loading dock components. An identification system is coupled with the plurality of loading dock components. A control panel is in signal communication with the plurality of loading dock components via the identification system. The identification system automatically cooperates with the control panel to define an operating sequence of the plurality of loading dock components. A power module is in signal communication with the control panel and an installed component of the plurality of loading dock components. The control panel provides instructions to the power module according to the operating sequence and the power module delivers a predetermined electrical current to the installed components of the plurality of loading dock components in a sequential pattern defined by the operating sequence.

To be able to activate a smoothing filter for a setpoint, with which the movement of a drive axis (A, Ai) of a drive unit (AE) can also be controlled during the movement without a negative effect on the movement, it is provided that the smoothing filter (10) is initialized with a setpoint profile (S.sub.init) so that a current movement phase ((S.sub.0, {dot over (S)}.sub.0, . . . , S.sub.0.sup.(x))) is continued continuously and the repeated time derivative (S.sup.(x+1)) of the highest time derivative (S.sup.(x)) of the setpoint (S(t), S(k)) is limited.

The garbage box includes an opening-closing unit on a predetermined surface, and the garbage box is installed such that the opening-closing unit faces a base surface with a predetermined interval from the base surface, the base surface being a floor surface or a ground surface. The garbage box opens the opening-closing unit when the garbage box detects that an autonomous mobile robot has come to a predetermined position in a vicinity of an installation position of the garbage box.

A system for assembling elements into framing components is provided along with a method for the use thereof. The system may comprise a frame, a fastening tool, a first conveyor, a second conveyor, and a holder. The pieces of the system may be connected so that they may operate automatically, with only minimal operation by a user. The system increases the speed, efficiency, precision, repeatability, and safety of assembling framing components.

An auger assembly for conveying a material includes an auger including a conveyor for transporting the material from a storage bin to a transport vehicle. The auger assembly also includes a power source operatively coupled to the conveyor to operate the conveyor. The auger assembly includes a first sensor, a second sensor, and a controller. The first sensor is engaged to the auger and configured to detect a flow of the material from an outlet of the auger. The second sensor is configured to detect a filling of the material inside the transport vehicle to a desired level. The controller is in communication with the first sensor, the second sensor, the power source and the auger, and is configured to control the power source based on inputs from at least one of the first sensor or the second sensor.