Systems, methods, and computer-readable media are disclosed for scanning and dimensioning items in motion. In one embodiment, an example system may include a first camera oriented along a vertical axis towards a gap between a first surface and a second surface, a first light emitting array positioned to emit light towards the gap, and a first light receiving array aligned with the light emitting array and configured to detect the light. The first light emitting array and the first light receiving array may be offset from the vertical axis, and the system may be configured to determine a first dimension of an item passing over the gap using the first light emitting array and the first light receiving array.

A diverter assembly (25) is provided for guiding articles from a single lane (54) to one of a plurality of lanes (13, 14). The assembly (25) has a pair of spaced apart guides (30) defining a guide channel (49) therebetween. The guides (30) are connected to a rotatably mounted support (24). A first actuator (22, 23) is provided operable to rotate the support (24) to pivot the guides (30), and thereby cause articles to be guided to a selected one of the plurality of lanes.

Some embodiments of the technology disclosed herein relate to a sensor device. An elongate sleeve has a first end and a second end and extends along a longitudinal axis. A plurality of sensors are fixed relative to the sleeve. A first endcap is coupled to the first end, where the first endcap has an endcap body. A first axle is coupled to the endcap body, where the first axle extends along the longitudinal axis and the first axle defines a retaining feature. An intermediate component is coupled to the first axle, and the intermediate component is selectively rotatable about the longitudinal axis. The sensor device has an orientation locking structure that is configured to be engaged to selectively fix the orientation of the intermediate component about the longitudinal axis relative to the endcap body.

A vacuum system (10) and method (100) used for creating a dynamically controlled vacuum system (10) for lifting processes (Wc) are disclosed. The compressed air used for an ejector (3) is varied by calculating the required vacuum levels (V.sup.−) during the lifting process (Wc). This reduces the air consumption.

A system (500) for distributing a stream of articles (100) at a fix pitch (P) includes a belt assembly (250) with belt segments (252) carrying a stream of articles (100), a sensor assembly (510) with sensors (512), a control system (550) interfacing with the belt assembly (250) and the sensor assembly (510), wherein the sensor assembly (510) provides measurements of initial positions of each article of the stream of articles (100) and transmits the measurements to the control system (550), wherein the control system (550) utilizes the measurements to determine deficits of the initial positions to final positions for each article based on a predefined pitch value (P), and wherein the control system (550) controls a speed of the plurality of belt segments (252) to provide the final positions for each article according to the predefined pitch value (P).

A radiation detector unit includes a read-out integrated circuit (ROIC) including a plurality of core circuit blocks located on a continuous uninterrupted substrate adjacent to one another along a first direction, and a plurality of radiation sensors bonded to a front side surface of the ROIC, where each radiation sensor of the plurality of radiation sensors is bonded to a respective core circuit block of the plurality of core circuit blocks of the ROIC. Additional embodiments include detector modules and detector arrays formed by assembling the detector units, and methods of operating and manufacturing the same.

A movement apparatus for objects configured for receiving an object from an infeed station and moving the object towards an outfeed station, comprising a movement surface comprising movement cells positioned on in a matrix fashion, positioned to operate with the object, wherein each movement cell has a direction of movement which can be individually controlled; a control system configured for defining a conveying trajectory in the movement surface for conveying the object from the infeed to the outfeed station; identifying trajectory cells belonging to the conveying trajectory and directing the direction of movement of each trajectory cell to move the object in the conveying trajectory; identifying, between the movement cells, convergence cells, defining a convergence zone adjacent to the conveying trajectory and, for each convergence cell, directing the direction of movement towards a central line of the conveying trajectory to maintain of the object inside the conveying trajectory.

A vibratory apparatus includes a deck and an exciter assembly coupled to the deck. The apparatus also includes a motion sensor, a weight sensor, and a control system coupled to the exciter assembly, the motion sensor, and the weight sensor. The control system is configured to pause the rate of travel of the material across the deck for a weighing interval, to receive the signal from the weight sensor representative of a material weight on the deck during the weighing interval, to resume the rate of travel for a transporting interval, to receive a signal from the motion sensor representative of a material flow rate during the transporting interval, to determine a material mass flow rate based on the signals from the weight sensor and the motion sensor and the weighing and transporting intervals, and to vary the operation of the exciter assembly according to the material mass flow rate.

An intensive quenching (IQ) apparatus and method of quenching heated parts is provided. The IQ apparatus includes a chute for placing parts into a tank including liquid quenchant. The parts fall through the quenchant in the chute and are received by a conveyor belt. The parts are then transported on the conveyor through an inner channel of a conduit. An agitation rate of the quenchant in the inner channel is increased by an agitator.

The present application discloses a method, system, and computer system for controlling a gating structure to mediate a flow of items an input source to a pick area. The system includes: (i) the gating structure, which is configured to use a plurality of gate elements to mediate a flow of items from the input source to the pick area, (ii) a sensor configured to provide a sensor output associated with the pick area, and (iii) a processor configured to provide a control input to the gating structure to adjust a configuration of one or more of the plurality of gating elements based at least in part on the sensor output. The sensor output comprises the sensor output comprises one or more of a flow rate, a number, and an orientation of objects in an area associated with picking of objects by one or more robots. The control input is determined based at least in part on one or more of the flow rate, the number, and the orientation of objects in the area associated with picking of objects by one or more robots.