A system includes a safety controller that, in operation, interrupts power to industrial automation devices or puts the system into a safe state upon command of a human operator. The system also includes an emergency stop switch circuit actuatable by a human operator and a human machine interface in data communication with the safety controller and the emergency stop switch circuit. The human machine interface includes integrated safety circuitry that, in operation, detects a change of state of the emergency stop switch circuit and provides a signal to the safety controller to interrupt power to the industrial automation devices or put the system into a safe state.

An automation operating and management system consolidates and analyzes inputs from multiple machines within an automated enterprise to predict failures and provide instructions for counteractions to prevent failures during machine operation, and to identify opportunities for efficiency improvement, including actions for reduction in peak power consumption demand within a facility including multiple machines. A machine can include a machine controller and at least one base layer controller, where the base layer controller acts as a low level controller to directly control the motion of elements in communication with the base layer control, according to parameters set by the machine controller. The base layer controller collects timing data for the elements under its control, compares the timing data with the parameters and sets an alarm when the timing data is outside of tolerance limits defined by the parameters.

The present invention provides a system and method for wirelessly controlling an operating device by way of a wireless connection between the operating device and a computing device. The computing device provides an interface for controlling the operating device. The interface includes a switch for use as a deadman switch, whereby releasing the switch will cease the operation of the operating device. The user may remotely control the operating device via the computing device while the switch is actuated. Upon releasing the switch, the computer device wirelessly halts the operating device for safety.

A manual pulse generating device includes a rotatable dial, a pulse generating unit configured to generate drive pulses for commanding axial movement in accordance with an amount of rotation of the dial, an enable switch configured to switch between enablement and disablement of axial movement in accordance with the drive pulses, and a casing having the dial and the enable switch disposed on a surface thereof, and accommodating the pulse generating unit in the interior thereof. The dial is mounted on one end side in a longitudinal direction of the casing, and on a front surface of the casing, and the enable switch is mounted on another end side, i.e., a side in the positive X direction, in the longitudinal direction of the casing, and on the front surface of the casing, or on a side surface of the casing that extends along a lateral direction of the casing.

A manual pulse generating device is equipped with a rotatable dial, a pulse generating unit configured to generate drive pulses for commanding axial movement in accordance with an amount of rotation of the dial, an enable switch configured to switch between enablement and disablement of axial movement in accordance with the drive pulses, and a casing having the dial and the enable switch disposed on a surface thereof, and configured to accommodate the pulse generating unit in the interior thereof. The guard configured to cover at least a portion of an outer circumferential surface of the dial is attached to the casing.

A robot system includes a robot, a control apparatus that controls the robot, a teaching apparatus having a first operation part that makes an emergency stop of a motion of the robot and teaching the motion of the robot, and an emergency stop processing apparatus having a second operation part that continues the motion of the robot after the first operation part is operated, wherein the second operation part is separately provided from the control apparatus.

An automation operating and management system consolidates and analyzes inputs from multiple machines within an automated enterprise to predict failures and provide instructions for counteractions to prevent failures during machine operation, and to identify opportunities for efficiency improvement, including actions for reduction in peak power consumption demand within a facility including multiple machines. A machine can include a machine controller and at least one base layer controller, where the base layer controller acts as a low level controller to directly control the motion of elements in communication with the base layer control, according to parameters set by the machine controller. The base layer controller collects timing data for the elements under its control, compares the timing data with the parameters and sets an alarm when the timing data is outside of tolerance limits defined by the parameters.

A system for controlling automation includes a machine which collects data generated by performance of an operation by the machine. A user device displays a machine control interface (MCI) corresponding to the machine. The MCI displays the collected data to a touch interface of the user device, and defines at least one touch activated user interface element (UIE) for manipulating the data. The user device can be enabled as an automation human machine interface (HMI) device for controlling an operation performed by the machine, such that a touch action applied to a UIE of the MCI controls the operation. A prerequisite condition to enabling the user device as an automation HMI device can include activation of an enabling switch selectively connected to the user device. The MCI can be stored in a memory of the enabling switch and retrieved from the enabling switch by the user device.

A system and method for controlling automation includes a machine performing at least one operation and including a sensor for generating data in response to a performance of the operation by the machine. Data generated by the sensor is stored for retrieval by a server in data memory storage. The server includes at least one display template for displaying the data, and the server generates a data display by populating the at least one display template with the data. The data template can be populated with data in real time, to display the data display immediate to the generation of the data. The display template includes a data feature which is differentiated for displaying the data feature in a mode determined by the data populating the data display. The data display can be displayed in real time by a user device in communication with the server.