The load is carried on a horizontal conveyor belt which is driven by a motor. The conveyor system is carried on a base which supports a number of lever arms. The lever arms are balanced by a fixed weight and by movable weights. There is a clutch and brake mechanism on the drive axis of the main drive motor so that the load may be accelerated or stopped. The movement of the levers is directly proportional to the load so that the braking or accelerating forces are also proportional to the load. The clutch and brake mechanism may be controlled by a cam and piston.

An article transport system with few missed detections, and a controller used in the system. The system includes: a conveyor that sequentially transports plural workpieces; a conveyor sensor that obtains conveyance operation information of the conveyor; an arrival sensor that senses the arrival of each workpiece; a camera that captures an image of each workpiece; a position detection processing section that detects the workpiece from the image, and identifies a position of the workpiece on the conveyor; a movement distance designation section that designates first and second movement distances; an image capturing control section that controls the camera to capture an image of the workpiece upon the conveyor advancing by the first movement distance after the arrival of the workpiece has been sensed, and each time the conveyor advances by the second movement distance; and a number designation section that designates an upper limit number for the detection process.

A transfer system is provided. The transfer system comprises a loading stage, configured to receive a product from a first movement system. The transfer system also comprises a gap stage, configured to receive the product from the loading stage and move the product at a speed. The speed is configured to separate the product from a subsequent product. The transfer system also comprises a detection stage, configured to identify the product by detecting a product identifier using a sensor. The transfer system also comprises a transfer system configured to move the product from through the loading stage, gap stage and detection stage to a second movement stage. The transfer system also comprises a controller configured to generate and send control signals to the transfer system and receive an identification of the product from the sensor.

According to an embodiment, an article conveyance sorting apparatus includes a distributing section, a first conveyance section, a second conveyance section, and a conveyance sorting section. The distributing section distributes an article in a first direction or a second direction based on a first distribution control signal or a second distribution control signal corresponding to a distinguishing result of the article distinguished based on article information. The first conveyance section receives the article distributed in the first direction. The second conveyance section receives the article distributed in the second direction. The conveyance sorting section sorts each of articles conveyed by the plurality of trays to a designated sorting destination.

Facility for sorting items comprising: at least one conveyor comprising supports designed to support the items, and at least one receiving device, the supports being designed to eject at least some of the items in succession into or onto the receiving device, the ejected items describing true paths (Tr) with respect to the receiving device, the true paths being liable to belong to a predefined set (Tr-Out) of potential paths considered as being incorrect. The facility further comprises: a detector designed to supply primary information relating respectively to true paths, and an analyzer designed to use the said primary information and to produce at least one secondary information item representative of the belonging of at least one of the true paths to the predefined set (Tr-Out).

A typing off-loading and item separation system to automatically separate different parcel types includes an feed conveyor, receiving conveyor, sorting conveyor, cameras and photoelectric eye. Overhead cameras and/or photoelectric sensors detect the item size and whether it is cubic in nature and type and size of its footprint. An in-line slide sorter having alternating conveyor rollers and pop-up belts pass through to, or divert items from a downstream conveyor. A vison based system may also be used to detect space between articles and insert articles in the unoccupied space to maximize conveyor area, volume, or density by controlling conveyor speed.

A transfer system is provided. The transfer system comprises a loading stage, configured to receive a product from a first movement system. The transfer system also comprises a gap stage, configured to receive the product from the loading stage and move the product at a speed. The speed is configured to separate the product from a subsequent product. The transfer system also comprises a detection stage, configured to identify the product by detecting a product identifier using a sensor. The transfer system also comprises a transfer system configured to move the product from through the loading stage, gap stage and detection stage to a second movement stage. The transfer system also comprises a controller configured to generate and send control signals to the transfer system and receive an identification of the product from the sensor.

The present disclosure relates to a pneumatic suction conveying apparatus for conveying granulated bulk materials and a corresponding method, comprising a pump unit with a vacuum pump and a suction volume, at least two suction lines, which is connected to the suction volume and extends towards storage containers for receiving bulk materials, the suction lines each comprising a conveying hopper for separating the bulk material and a stop valve for blocking the suction line. Hereby, in the suction line there is each provided a closed control loop comprising an adjustable throttle valve and a flow sensor provided in the suction line, the control loop being adapted and designed to adjust the throttle valve depending on a measurement of the flow sensor.

There is provided a method and system for monitoring a component moving in a delivery tube of a feed system in an automated production line. The method includes determining a velocity of the component that moves through the delivery tube and comparing the velocity to a predefined velocity range. The system includes at least one sensor configured to detect the component when the component passes through a first point and through a second point within the delivery tube;

and a controller, wherein the at least one sensor is operatively coupled to the controller. The sensor may be configured to send a first signal when the component passes through the first point and a second signal when the component passes through the second point and the controller may be configured to determine velocity of the component by measuring a time interval between the first signal and the second signal.

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.