A method of determining a configuration state of an I/O module connected to a fieldbus controller is disclosed, the method comprising the steps of receiving from the I/O module a key ID, comparing the key ID with at least one key ID stored on the fieldbus controller, and configuring the I/O module when the received key ID does not correspond to the at least one stored key ID stored. Further, a circuit for configuring a digital input of a fieldbus controller as either a PNP input or an NPN input is provided comprising a control circuit including a reference input, a first selection input, and a control output. The circuit also comprises a data circuit including a second selection input electrically connected to the control output, a data input electrically coupled to the digital input, and a data output.

A reversible fuse support block includes a molding, a terminal, and a fuser interface. The molding may be installed within a housing in a first position and a second position, wherein the second position is rotated 180 degrees relative to the first position. The terminal couples to the molding and includes a plurality of apertures disposed in a pattern. The fuse interface receives a first end of a fuse. The fuse interface couples to the terminal in a first arrangement and a second arrangement such that when the fuse interface is installed in the first arrangement and the molding is installed in the first position, the fuse interface is disposed in substantially the same position relative to a corresponding fuse interface on a fuse support block as when the fuse interface is installed in the second arrangement and the molding is installed in the second position.

The invention relates to a method and to a system for optimizing the commissioning of at least one of a plurality of field devices in an automation technology system, which are used in different applications, wherein the system comprises at least: one database for saving application information and device types of the plurality of field devices and for saving parameter sets of the plurality of field devices; an electronic computation unit that accesses the remotely arranged database and classifies, assigns, compares, and/or processes the data saved there and has an algorithm for creating and proposing an optimal parameter set; software for supporting a user during commissioning of one of the plurality of field devices, wherein the electronic computation unit is operated by means of the software.

A reversible fuse support block includes a molding, a terminal, and a fuser interface. The molding may be installed within a housing in a first position and a second position, wherein the second position is rotated 180 degrees relative to the first position. The terminal couples to the molding and includes a plurality of apertures disposed in a pattern. The fuse interface receives a first end of a fuse. The fuse interface couples to the terminal in a first arrangement and a second arrangement such that when the fuse interface is installed in the first arrangement and the molding is installed in the first position, the fuse interface is disposed in substantially the same position relative to a corresponding fuse interface on a fuse support block as when the fuse interface is installed in the second arrangement and the molding is installed in the second position.

A reversible fuse support block includes a molding, a terminal, and a fuser interface. The molding may be installed within a housing in a first position and a second position, wherein the second position is rotated 180 degrees relative to the first position. The terminal couples to the molding and includes a plurality of apertures disposed in a pattern. The fuse interface receives a first end of a fuse. The fuse interface couples to the terminal in a first arrangement and a second arrangement such that when the fuse interface is installed in the first arrangement and the molding is installed in the first position, the fuse interface is disposed in substantially the same position relative to a corresponding fuse interface on a fuse support block as when the fuse interface is installed in the second arrangement and the molding is installed in the second position.

A system for monitoring and controlling aquatic equipment is provided. The system includes a variable speed pump, a controller configured to determine operational parameters of the variable speed pump and to control operation of the variable speed pump, and a wireless communication system operatively coupled to the controller. The wireless communication subsystem is configured to transmit one or more of the operational parameters of the variable speed pump to a device over a WiFi wireless and/or a Bluetooth wireless connection. The wireless communication subsystem is configured to receive one or more control parameters from the device, and the controller controls operation of the variable speed pump based on the one or more control parameters.

Disclosed is a system for controlling pool/spa components. More particularly, disclosed is a system for controlling pool/spa components including a display screen and one or more processors presenting a control user interface for display on the display screen, wherein the control user interface includes a home screen comprising a first portion containing a first plurality of buttons and/or controls for controlling a first group of the plurality of pool/spa components associated with a first body of water, and a second portion containing a second plurality of buttons and/or controls for controlling a second group of the plurality of pool/spa components associated with a second body of water.

Present embodiments include an automation control system that includes an input/output device module with a device bus therein. The input/output module also includes a first bus contact on a first side of the input/output device module and communicatively coupled with a first end of the device bus, and a second bus contact on a second side of the input/output device module and communicatively coupled with a second end of the device bus. The second side generally faces an opposite direction from the first side and the input/output device module is configured to be coupled with additional input/output device modules positioned on the first and second sides of the input/output device module via the first and second bus contacts. Further, the first and second bus contacts are positioned on non-lateral surfaces of the input/output device module, the first and second contacts include spring-loaded connectors, the first and second contacts include two-prong or three-prong forks, or the input/output device module is a terminal block.

The invention relates to a method and to a system for optimizing the commissioning of at least one of a plurality of field devices in an automation technology system, which are used in different applications, wherein the system comprises at least: one database for saving application information and device types of the plurality of field devices and for saving parameter sets of the plurality of field devices; an electronic computation unit that accesses the remotely arranged database and classifies, assigns, compares, and/or processes the data saved there and has an algorithm for creating and proposing an optimal parameter set; software for supporting a user during commissioning of one of the plurality of field devices, wherein the electronic computation unit is operated by means of the software.

Present embodiments include an adaptable automation control component that includes a base capable of communicatively coupling with a system bus and with a functional module that includes communication and control circuitry. The adaptable automation control component also includes a device power bus including electrical contacts that are capable of communicatively coupling the adaptable automation control component with a separate automation control component, and an activation mechanism including circuitry capable of continuing the device power bus when the activation mechanism is engaged, and capable of discontinuing the device power bus when the activation mechanism is disengaged. The adaptable automation control component facilitates functionality of the adaptable automation control component as an input/output module or a power distribution module depending on whether the activation mechanism is engaged or disengaged.