A device and method for calculating optimum values using a proportional-integral-derivative (PID) control loop. A user may select from a list of manufacturers, devices, systems and applications. The user selects the appropriate combination, and a set of parameters from a pre-populated database is loaded. The user may adjust any of the default values if so desired. The present invention also provides the ability to adjust optional fields based on specific manufacture PID algorithms, such as minimum output and maximum output, PID execution rate, and percentage of stage capacity per design. Optimum PID parameters are calculated based on the specific device and optional field values and are used by a PID control unit to have the device efficiently achieve desired results.

According to one aspect of this disclosure, a distributed control system may include a diagnostic engine, a plurality of computing resources generating diagnostic parameters for transmission to the diagnostic engine, a first communication link operatively coupling the plurality of computing resources to one another, a second communication link operatively coupling the plurality of computing resources to the diagnostic engine, and a remote connection operatively coupling the diagnostic engine to a remote computing resource. The diagnostic parameters may indicate one or more conditions for at least one of the plurality of computing resources. The diagnostic engine locally observes the diagnostic parameters of the plurality of computing resources via the first communication link, and the remote computing resource initiates operation of the diagnostic engine via the remote connection and evaluates the diagnostic parameters remotely.

The invention relates to a parameterizable energy supply device comprising; a wireless communication interface for capturing parameterization data for arameterizing the parameterizable energy supply device by means of a communication network; and a processor which is designed to control at least one operational parameter of the parameterizable energy supply device based on the captured parameterization data.

A consumer appliance, as provided herein, may include a cabinet, a user interface attached to the cabinet, a motor mounted within the cabinet, and a control board in electrical communication with the user interface and the motor. The user interface may include one or more connected electrical elements. The control board may be configured to initiate an initial operation. The initial operation may include activating the control board and detecting the one or more connected electrical elements from a predetermined plurality of potential electrical elements. The initial operation may further include selecting an operating personality from a plurality of preset personalities based on detecting the one or more connected electrical elements. The initial operation may still further include directing the motor according to the selected operating personality.

The invention relates to a method for the traceable programming and/or configuration of a device, in particular of an embedded device, in which a) data are transmitted to the device from a programming system, with the transmitted data including code executable by the device and being generated from source code; b) a first unique identifier is produced on the basis of at least some of the transmitted data and of at least some of the source code and of an identification of the device; c) the first unique identifier is stored in the device; and d) at least the transmitted data used for the first unique identifier, the source code used for the first unique identifier, and the first unique identifier are stored in a memory device independent of the device.

The invention relates to an installation method for setting up a control unit in a conveying device, wherein a first control unit controls an upstream first conveyor segment and a second control unit controls a downstream second conveyor segment. The method according to the invention comprises the steps of: placing an object on a first conveyor segment; activating a learning mode in a first and second control unit; activating a first and second conveyor drive by means of the respective first and second control unit; automatically conveying the object in the direction of the second conveyor segment; and storing an installation parameter in the second control unit depending on the triggering of the first or second sensor signal.

The invention relates to a conveying device for conveying objects comprising a plurality of conveyor segments, each conveyor segment having a control unit for controlling the conveyor drive, and a bus communication, wherein each control unit is connected to the bus communication. Each control unit has a microprocessor for processing control signals, a first electronic memory connected to the microprocessor, in which a first control configuration is stored, and a second electronic memory in which a second control configuration is stored. The microprocessor is adapted to control the conveyor drive in a first operating mode with the control configuration stored in the first memory, to load the second control configuration from the second memory into the first memory when a configuration change command is received, and to control the conveyor drive in a first operating mode with the control configuration stored in the first memory.

The present disclosure relates to a parameterizable automation technology device. The parameterizable automation technology device includes a memory, a wireless communications interface, and a processor. The memory is configured to prestore a device parameter of the parameterizable automation technology device. The wireless communication interface is configured to receive update data to update the prestored device parameter via a communication network. The processor is configured to update the prestored device parameter based on the received update data and to adjust an operation of the parameterizable automation technology device based on the updated prestored device parameter.

The invention relates to a control apparatus (3) for an HVAC system (5), wherein the control apparatus (3) has a communication module (33) for communicating with one or more components of the HVAC system (5). The control apparatus comprises a passive NFC transponder (34), which is set up to receive and store a unique identifier (341) of each of the one or more components from a mobile service apparatus (2) before a power supply for the control apparatus (3) is switched on, and a control module (35) which is set up to access stored identifiers (341) after a power supply for the control apparatus (3) has been switched on and to transmit control signals to components determined by the identifiers via the communication module (33). The invention also relates to a mobile service apparatus (2) and to components in the form of drives (1), sensor apparatuses, regulators, operating devices and/or communication devices of the HVAC system (5).

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.