Abstract: 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.

Abstract: 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.

Abstract: An input/output (I/O) device for an automation control system includes a base portion configured to communicatively connect the I/O device with at least one other I/O device, an I/O module physically and communicatively connected to the base portion and comprising I/O communication circuitry, a terminal block physically and communicatively connected to the base portion, and an ejection device configured to eject the I/O module or the terminal block from the base portion by pushing the I/O module or the terminal block out of engagement with the base portion when activated.

Abstract: Systems and methods are provided for aligning status indicators on a terminal block of an I/O device by locating the status indicators directly adjacent to or integrated directly within their respective terminals on the terminal block. The status indicators are illuminated by LEDs or other light emitters disposed within a housing of the I/O device. Light from the LEDs are directed to the status indicators by light pipes disposed within the housing of the I/O device. LED activation circuitry disposed within the housing determines a manner in which to activate the LEDs to illuminate the status indicators based on inputs and outputs between the I/O device and a controlled process. In certain embodiments, the status indicators are disposed on a raised section of the I/O device, which may be part of a removable LED indication assembly including the LEDs, light pipes, and LED activation circuitry.

Abstract: Systems and methods are provided for aligning status indicators on a terminal block of an I/O device by locating the status indicators directly adjacent to or integrated directly within their respective terminals on the terminal block. The status indicators are illuminated by LEDs or other light emitters disposed within a housing of the I/O device. Light from the LEDs are directed to the status indicators by light pipes disposed within the housing of the I/O device. LED activation circuitry disposed within the housing determines a manner in which to activate the LEDs to illuminate the status indicators based on inputs and outputs between the I/O device and a controlled process. In certain embodiments, the status indicators are disposed on a raised section of the I/O device, which may be part of a removable LED indication assembly including the LEDs, light pipes, and LED activation circuitry.

Abstract: 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.

Abstract: An input/output (I/O) device for an automation control system includes a base portion configured to communicatively connect the I/O device with at least one other I/O device, an I/O module physically and communicatively connected to the base portion and comprising I/O communication circuitry, a terminal block physically and communicatively connected to the base portion, and an ejection device configured to eject the I/O module or the terminal block from the base portion by pushing the I/O module or the terminal block out of engagement with the base portion when activated.

Abstract: An electronics module housing includes an external recess adapted to receive an associated DIN rail or other associated mounting structure. A latch mechanism is associated with the external recess and is adapted to engage the DIN rail. An electronics circuit board is located in the housing. An electrical connector is physically and electrically connected to the circuit board. The electrical connector includes: (i) a connector body; (ii) a plurality of electrical contacts secured to said connector body and comprising contact pins physically and electrically connected to the circuit board; and (iii) a ground contact secured to the connector body and including a ground pin physically and electrically connected to said circuit board. The ground contact includes a ground contact body that extends from the connector body into the housing recess. The ground contact body includes a ground contact face located adjacent the recess and adapted to contact the associated DIN rail to which the module is mounted.

Abstract: An input/output (I/O) device for an automation control system includes a base portion configured to communicatively connect the I/O device with at least one other I/O device, an I/O module physically and communicatively connected to the base portion and comprising I/O communication circuitry, a terminal block physically and communicatively connected to the base portion, and an ejection device configured to eject the I/O module or the terminal block from the base portion by pushing the I/O module or the terminal block out of engagement with the base portion when activated.

Abstract: An electronics circuit board includes a periphery defined by a plurality of edges. At least one power contact is located adjacent a first one of said edges and a plurality of data contacts are located adjacent a second one of said edges. The first and second edges are arranged transversely relative to each other. The circuit board is operatively installed on a base that includes a power connector and a data connector. At least one power contact of the circuit board is operably engaged with the power connector and the plurality of data contacts of the circuit board are operably engaged with said data connector. The power connector is located adjacent said first edge of the circuit board and the data connector is located adjacent a second edge of the circuit board.

Abstract: A serial optical data transmission system is provided. The serial optical data transmission system includes a displaceable optical pathway disposed adjacent to a slot configured to receive a first monitoring and/or control module. The optical pathway is biased towards a serial optical data bus position for transmission of optical data to or from at least one second monitoring and/or control module when the first monitoring and/or control module is removed from the slot. Further, the optical pathway is displaced from the serial optical data bus position when the first monitoring and/or control module is in the slot.

Abstract: A contact device enables a contact method for RIUP operations relative to a backplane. The contact device includes first and second contact portions, each including first and second spaced-apart contact arms. The first and second contact portions are located relative to each other on the backplane such that when the contact device is in a first operative condition, the respective first contact arms abut each other and define a first electrical conduction path and the second contact arms are spaced from each other.

Abstract: A torsional electrical contact includes a body including a helix with N turns around an axis, N?1. The body includes first and second ends. First and second contact arms extend outwardly away from the helix. The contact arms include respective distal ends. The arms define a contact angle ?. At least one of the first and second contact arms is selectively resiliently movable toward the other of the first and second contact arms to reduce the contact angle ?. One or more contacts are installed in a module and/or connected to an electronic component. A module including first and second contacts can be configured in a first condition in which the contacts are connected directly to each other or a second condition in which the contacts are engaged with respective parts of a circuit board or other component inserted into the housing according to a disclosed method.

Abstract: A contact device enables a contact method for RIUP operations relative to a backplane. The contact device includes first and second contact portions, each including first and second spaced-apart contact arms. The first and second contact portions are located relative to each other on the backplane such that when the contact device is in a first operative condition, the respective first contact arms abut each other and define a first electrical conduction path and the second contact arms are spaced from each other.

Abstract: An electronics circuit board includes a periphery defined by a plurality of edges. At least one power contact is located adjacent a first one of said edges and a plurality of data contacts are located adjacent a second one of said edges. The first and second edges are arranged transversely relative to each other. The circuit board is operatively installed on a base that includes a power connector and a data connector. At least one power contact of the circuit board is operably engaged with the power connector and the plurality of data contacts of the circuit board are operably engaged with said data connector. The power connector is located adjacent said first edge of the circuit board and the data connector is located adjacent a second edge of the circuit board.

Abstract: A torsional electrical contact includes a body comprising a helix including N helical turns around a longitudinal axis, wherein N?1. The body further includes first and second opposite ends that are spaced longitudinally from each other. First and second contact arms extend outwardly away from the helix at the opposite first and second ends of the body, respectively. The first and second contact arms include respective distal ends defined by a part of the contact arm that is located a maximum orthogonal distance from the longitudinal axis. The first and second arms define a contact angle ? measured between a first reference plane in which the longitudinal axis lies and that intersects the distal end of the first contact arm and a second reference plane in which the longitudinal axis lies and that intersects the distal end of the second contact arm.

Abstract: Systems and methods are provided for aligning status indicators on a terminal block of an I/O device by locating the status indicators directly adjacent to or integrated directly within their respective terminals on the terminal block. The status indicators are illuminated by LEDs or other light emitters disposed within a housing of the I/O device. Light from the LEDs are directed to the status indicators by light pipes disposed within the housing of the I/O device. LED activation circuitry disposed within the housing determines a manner in which to activate the LEDs to illuminate the status indicators based on inputs and outputs between the I/O device and a controlled process. In certain embodiments, the status indicators are disposed on a raised section of the I/O device, which may be part of a removable LED indication assembly including the LEDs, light pipes, and LED activation circuitry.

Abstract: An input/output (I/O) device for an automation control system includes a base portion configured to communicatively connect the I/O device with at least one other I/O device, an I/O module physically and communicatively connected to the base portion and comprising I/O communication circuitry, a terminal block physically and communicatively connected to the base portion, and an ejection device configured to eject the I/O module or the terminal block from the base portion by pushing the I/O module or the terminal block out of engagement with the base portion when activated.

Abstract: Systems and methods are provided for aligning status indicators on a terminal block of an I/O device by locating the status indicators directly adjacent to or integrated directly within their respective terminals on the terminal block. The status indicators are illuminated by LEDs or other light emitters disposed within a housing of the I/O device. Light from the LEDs are directed to the status indicators by light pipes disposed within the housing of the I/O device. LED activation circuitry disposed within the housing determines a manner in which to activate the LEDs to illuminate the status indicators based on inputs and outputs between the I/O device and a controlled process. In certain embodiments, the status indicators are disposed on a raised section of the I/O device, which may be part of a removable LED indication assembly including the LEDs, light pipes, and LED activation circuitry.

Abstract: 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.