A system for controlled distribution of components, the system including a vibrating bowl provided with an enclosure having a wall extending right around an axis of revolution of the bowl and in which the components are placed in bulk, and an articulated gripping arm provided to distribute the components to the automatic assembly installation, the vibrating bowl including an ascending helical ramp extending along an internal face of the wall between a base and an upper edge of the vibrating bowl constituting an exit of the ramp, the components being able to travel along this ramp towards a supply platform, particularly a slide, on which at least one component is arranged in advance of its seizure by the articulated gripping arm, the supply platform being connected to the exit and extending above or in the enclosure of the vibrating bowl.

A system and method for determining and controlling a speed of a conveyor belt configured for transferring material from a source of the material to a haul vehicle includes a motor and associated head pulley shaft operatively coupled to a conveyor belt head pulley configured for driving the conveyor belt. The motor is connected to a conveyor belt tensioner block configured to enable adjustment of a tension in the conveyor belt, and the head pulley shaft is rotatably supported within the conveyor belt tensioner block. A speed ring gear is mounted on the head pulley shaft and located at least partially within a bore through the conveyor belt tensioner block. A speed sensor is mounted on the conveyor belt tensioner block in a position radially outward from teeth of the speed ring gear as the speed ring gear and head pulley shaft rotate within the bore through the belt tensioner block. The speed sensor is configured to generate signals indicative of the speed of rotation of the head pulley shaft and speed ring gear. A system controller determines a speed of the conveyor belt from the speed of rotation of the head pulley shaft and speed ring gear, and controls the speed of the conveyor belt to control an amount and rate of transfer of material along the conveyor belt from the source of material to the haul vehicle during a time period.

A validation method includes a series of steps of acquiring a set of input data with a set of operating parameters, carrying out a reference milling operation of a first master workpiece and measuring values of the machining forces which are applied by a milling tool, determining specific force coefficients representative of the machining forces, carrying out an orthogonal cut of a second master workpiece and measuring values of the geometric sizes, calculating a tertiary thermal flux generated during the orthogonal cut, calculating a final temperature from the tertiary thermal flux, and comparing the final temperature with a critical temperature to validate or reject the set of operating parameters, the method enabling a temperature criterion to be established in a simple, rapid and low-cost manner to validate or reject the set of operating parameters to ensure the material health of a workpiece to be machined while maximizing the productivity.

A control system includes a plurality of driving devices that are connected to a network and drive a plurality of control targets, a control device that controls the plurality of driving devices via the network, and a teaching device for teaching operations of corresponding control targets to the plurality of driving devices. The teaching device transmits a command for driving the corresponding control target to at least one driving device among the plurality of driving devices via the network.

A system and method for determining and controlling a speed of a conveyor belt configured for transferring material from a source of the material to a haul vehicle includes a motor and associated head pulley shaft operatively coupled to a conveyor belt head pulley configured for driving the conveyor belt. The motor is connected to a conveyor belt tensioner block configured to enable adjustment of a tension in the conveyor belt, and the head pulley shaft is rotatably supported within the conveyor belt tensioner block. A speed ring gear is mounted on the head pulley shaft and located at least partially within a bore through the conveyor belt tensioner block. A speed sensor is mounted on the conveyor belt tensioner block in a position radially outward from teeth of the speed ring gear as the speed ring gear and head pulley shaft rotate within the bore through the belt tensioner block. The speed sensor is configured to generate signals indicative of the speed of rotation of the head pulley shaft and speed ring gear. A system controller determines a speed of the conveyor belt from the speed of rotation of the head pulley shaft and speed ring gear, and controls the speed of the conveyor belt to control an amount and rate of transfer of material along the conveyor belt from the source of material to the haul vehicle during a time period.

A server is connected to machines that perform cutting machining via a network. A common database shared by the machines is stored in the server, the database includes machining result information used in steps included in a cutting machining process performed by the machine and information on a use frequency of the machining result information. A machining result information presentation request to present machining result information that satisfies cutting conditions input by an operator of the machine is received from the machine. When the machining result information presentation request is received, the machining result information that satisfies the cutting conditions is extracted from the database and is presented to the machine based on the use frequency of the machining result information. A machining program is created based on machining result information selected by the operator among pieces of machining result information from the machine and is presented to the machine.

A controller is provided with a repeated control unit configured to calculate a position compensation value, based on a position command for each control period of a motor, a position deviation, which is the difference between the position command and a position of the motor, and a parameter for repeated control, and a machine learning device configured to predict the position compensation value calculated by the repeated control unit, and the machine learning device constructs a learning model so as to minimize an objective function based on the position command, the position deviation, and the position compensation value.

Disclosed are various embodiments of lock devices, systems, and methods. A lock of the application can include an internal mechanism to permit backdriven operation and lost motion operation. In one form the lock can be made from an assembly of parts that have locating features that require one way installation/assembly. The lock can include an internal power source capable of driving electronics used to determine handedness of a door.

Systems and methods for construction with detection, guidance, and/or feedback are disclosed. A system may include one or more of the following subsystems: (1) a detection subsystem, (2) a computer subsystem, (3) a translation subsystem, (4) a control subsystem, and/or (5) a user feedback subsystem. The detection subsystem may comprise one or more cameras, scanners, or sensors for detecting information associated with a space, one or more workpieces, or one or more tools. The computer subsystem may be adapted to receive data from the detection subsystem and to use the data received from the detection subsystem to make calculations for a desired construction project.

Techniques for assessing and managing versions of a configuration file associated with a modular control system of a process plant are described. According to certain aspects, systems and methods device may access data associated with multiple versions of a configuration file, including a computing device version and a control version, as well as a last backup instance of the configuration file. The systems and methods may compare the versions and determine any discrepancies between the versions, including which of the versions is the most recent. The systems and methods may present information associated with the comparison to enable a user to select which of the versions may be need to be updated, resolved, or provided to the controller so that the modular control system may be properly configured.