Abstract: A speed control system for sorters (e.g. sliding shoe sorters) comprises a sensor for measuring a sorter current speed of a sorter and a speed controller for setting peripheral conveyor commanded speeds for peripheral conveyors in communication with the sorter. During acceleration or deceleration of the sorter (e.g., in response to start or stop events of the sorter, or from one operating speed to another operating speed), the speed controller sets the peripheral conveyor commanded speeds to match or track the sorter current speed in order to ramp up or ramp down speeds of the peripheral conveyors with that of the sorter, which accelerates or decelerates more slowly than the peripheral conveyors. The speed controller may control the speed of different types of peripheral conveyors (e.g., upstream, intermediate, downstream) in various ways based on the type of the peripheral conveyors and/or based on user-configurable exception settings.

Abstract: A speed control system for sorters (e.g. sliding shoe sorters) comprises a sensor for measuring a sorter current speed of a sorter and a speed controller for setting peripheral conveyor commanded speeds for peripheral conveyors in communication with the sorter. During acceleration or deceleration of the sorter (e.g., in response to start or stop events of the sorter, or from one operating speed to another operating speed), the speed controller sets the peripheral conveyor commanded speeds to match or track the sorter current speed in order to ramp up or ramp down speeds of the peripheral conveyors with that of the sorter, which accelerates or decelerates more slowly than the peripheral conveyors. The speed controller may control the speed of different types of peripheral conveyors (e.g., upstream, intermediate, downstream) in various ways based on the type of the peripheral conveyors and/or based on user-configurable exception settings.

Abstract: A voice control interactive system and method to provide a hands-free operation for the operator to monitor and control multiple conveyors in a warehouse. The system comprises a first computing device and a second computing device. The first computing device is configured to receive a transmission from the second computing device, the transmission including information relating to a verbal command spoken by an operator associated with the second computing device. The first computing device is configured to generate a response signal in response to the transmission. The response signal includes information relating to a response for the verbal command. The information is generated based on a location of the second computing device. Generating the response signal includes identifying an optimal route information for the second computing device to reach a location of the first computing device.

Abstract: A voice control interactive system and method to provide a hands-free operation for the operator to monitor and control multiple conveyors in a warehouse. The system comprises a first computing device and a second computing device. The first computing device receives an audio signal generated by a second computing device and generates a control signal and a response signal in response to the audio signal. The audio signal comprises information relating to a verbal command spoken by an operator associated with the second computing device. The response signal comprises information relating to a response for the verbal command, wherein the information is generated based on a location of the second computing device. The control signal comprises information to control a conveyor.

Abstract: A voice control interactive system and method to provide a hands-free operation for the operator to monitor and control multiple conveyors in a warehouse. The system comprises a first computing device and a second computing device. The first computing device receives an audio signal generated by a second computing device and generates a control signal and a response signal in response to the audio signal. The audio signal comprises information relating to a verbal command spoken by an operator associated with the second computing device. The response signal comprises information relating to a response for the verbal command, wherein the information is generated based on a location of the second computing device. The control signal comprises information to control a conveyor.

Abstract: A small radius- or zero radius-turn vehicle that may be steered by differentially-driven rear drive wheels and by at least one electronically-controlled, steerable front wheel. A device, e.g., one or more levers, may be provided that controls both speed and direction of the drive wheels. A sensor may be provided that detects a position of the lever(s). A controller may calculate a steering angle of the front wheel based upon the position, and issue a command to an actuator associated with the front wheel. The actuator may rotate the front wheel to an electronically calculated steering angle in response to the command.

Abstract: A soil penetrating apparatus having an automatic tool (e.g., aerator tine) depth control system and method. The system includes an actuator that sets and controls tine depth, a sensor that monitors tine depth, and a controller that controls the actuator in response to the sensor. In some embodiments, the actuator is a hydraulic actuator, wherein once tine depth is set, flow to the actuator is bypassed. A relief may be provided to allow the tines to lift to a shallower depth temporarily when soil hardness exceeds a threshold. The system may then automatically return the tines to the pre-selected depth once soil conditions permit.

Abstract: A soil penetrating apparatus having an automatic tool (e.g., aerator tine) depth control system and method. The system includes an actuator that sets and controls tine depth, a sensor that monitors tine depth, and a controller that controls the actuator in response to the sensor. In some embodiments, the actuator is a hydraulic actuator, wherein once tine depth is set, flow to the actuator is bypassed. A relief may be provided to allow the tines to lift to a shallower depth temporarily when soil hardness exceeds a threshold. The system may then automatically return the tines to the pre-selected depth once soil conditions permit.

Abstract: Embodiments of the present disclosure provide systems, apparatus and methods for device management and tracking. Embodiments further disclose systems, apparatus and methods for conserving battery power to extend the operational life of the device. Tracking features may include redundant elements or operations for determining a device's movement or location. Such redundant elements or operations may be prioritized based upon power consumption rates associated with the element or operation. System features may include management controls for tracking, alerts and operations. The management controls may be operational through monitoring devices, web portals or other remote devices.

Abstract: Embodiments of the present disclosure provide systems, apparatus and methods for device management and tracking. Embodiments further disclose systems, apparatus and methods for conserving battery power to extend the operational life of the device. Tracking features may include redundant elements or operations for determining a device's movement or location. Such redundant elements or operations may be prioritized based upon power consumption rates associated with the element or operation. System features may include management controls for tracking, alerts and operations. The management controls may be operational through monitoring devices, web portals or other remote devices.