An electric motor includes a rotor assembly rotatable about a vertical center axis, a stator assembly around the rotor assembly, a housing inside of which the stator assembly is fixed, and a bearing mechanism rotatably supporting the rotor assembly. The housing includes a cylindrical wall portion inside of which the stator assembly is located, a bottom at a bottom vertical end of the cylindrical wall portion and extending radially outward, and a cover plate on one side of the stator assembly opposite to the bottom. The cover plate includes electrically conductive elements and at least one columnar projection protruding away from the stator assembly so that the at least one projection contacts at least one grounding contact of a controller on one side of the cover plate, the controller being electrically connected to a ground potential through the housing.

An I/O interface configuration device for configuring I/O interfaces comprises an input interface, an output interface, a storage unit, a detecting pin, a converting unit and a computing unit. The input interface electrically connects to a controlling port of a controlling circuit to receive a data type. The output interface electrically connects to a controlled port of a controlled device to output another data type. The storage unit stores a plurality of configuration files, one of the configuration files corresponds to a circuit type of the controlling circuit. The detecting pin is adapted to retrieve the circuit type. The converting unit converts the data type to said another data type and selectively outputs said another data type from the output interface. The computing unit loads the configuration file corresponding to the circuit type and control the converting unit to configure the I/O interface according to the configuration file.

It is an object of the present invention to provide an encoder that is easier to use.

An encoder 1 used in a numerical control device includes a signal generation unit configured to generate a digital signal, and a configuration information output unit configured to output configuration information that determines operation of the signal generation unit, in which the configuration information output unit includes a voltage level acquisition unit that acquires a voltage level to be input, a configuration information selection unit that selects configuration information according to the acquired voltage level among a plurality of types of configuration information, and a configuration information transmission unit that transmits the selected configuration information to the signal generation unit.

The present disclosure relates to control systems for controlling and dynamically configuring a production line. The production line includes one or multiple peripheral devices respectively located throughout the production line. A controller, or control unit, may, in one embodiment, extract binary instructions included in a file received from a source external to the controller, and the controller operates each of the devices on the production line based on the binary instructions embedded in the file.

Robots may be instantiated on-demand and may be adaptive in response to an environment, application, or event change. The adapted robot may switch functions in order to perform selective operations within medicine, agriculture, military, entertainment, or manufacturing, among other things

Robots may be instantiated on-demand and may be adaptive in response to an environment, application, or event change. The adapted robot may switch functions in order to perform selective operations within medicine, agriculture, military, entertainment, or manufacturing, among other things.

The invention relates to a method for switching the production of a flat film machine (100) from a feed product (EP) to a follow-on product (FP), comprising the following steps: recognizing a switching request for a switch from the feed product (EP) to the follow-on product (FP), determining a current feed control value (ES) of at least one control variable (SG) of the flat film machine (100) for the feed product (EP), determining a follow-on control value (FS) of the same at least one control variable (SG) for the follow-on product (FP), generating a control signal (SS) for a defined variation of the at least one control variable (SG) of the flat film machine (100) from the feed control value (ES) to the follow-on control value (FS).

A method for configuring hardware modules in an automation system includes the steps opening or creating a project in a project configuration software package, opening or generating, in the project, where a station has a number of slots, opening a hardware catalog that includes a plurality of hardware module master data records, inserting at least one hardware module master data record for a hardware module from the hardware catalog (into the station, wherein a customization step is performed for the at least one hardware module master data record, where at least one environmental parameter is specified which represents the ambient conditions at the deployment location of the at least one hardware module, and saving the station having the at least one hardware module master data record inserted into the station and with its at least one environmental parameter.

A computation unit having at least one computation core, a primary memory device, and at least one main connecting unit for connecting the at least one computation core to the primary memory device, the computation unit having at least two functional units, at least a first functional unit of the at least two functional units being embodied a) to receive first data from at least one further functional unit of the at least two functional units, and/or b) to transmit second data to at least one further functional unit of the at least two functional units.

A process module (110) is automatically configured for operation in a plant (B). During the operation of the process INmodule (110) in a first phase (1) in a first operational environment (A), operational data (DATA) that is related to the process module (110) is received by a computer data system (120). In a second phase (2), when the process module (110) is connected to a N second operational environment (B), operational data (DATA) is received again. The computer data system (120) has a reply function that receives and processes a query (Q.) and provides a response (R). Processing comprises to process the operational data (DATA) that was received during in the first and second phases. The process module (110) is then configured by using configuration parameters (150) that are derived from the response (R).