Abstract: Methods and apparatus to communicatively coupled field devices to a remote terminal unit are disclosed. The example apparatus includes a base rack for a remote terminal unit in a process control system. The example apparatus further includes a first termination module to be inserted in a first termination slot of the base rack. Wires communicatively coupled to a field device are to be terminated on the first termination module. The example apparatus also includes a first control module separate from the first termination module to be inserted in a first control slot of the base rack. The first control module is to be communicatively coupled with the first termination module via a backplane of the base rack. The first control module is to control communications with the field device.

Abstract: Methods and apparatus to communicatively coupled field devices to a remote terminal unit are disclosed. The example apparatus includes a base rack for a remote terminal unit in a process control system. The example apparatus further includes a first termination module to be inserted in a first termination slot of the base rack. Wires communicatively coupled to a field device are to be terminated on the first termination module. The example apparatus also includes a first control module separate from the first termination module to be inserted in a first control slot of the base rack. The first control module is to be communicatively coupled with the first termination module via a backplane of the base rack. The first control module is to control communications with the field device.

Abstract: Methods and apparatus to communicatively coupled field devices to a remote terminal unit are disclosed. The example apparatus includes a base rack for a remote terminal unit in a process control system. The example apparatus further includes a first termination module to be inserted in a first termination slot of the base rack. Wires communicatively coupled to a field device are to be terminated on the first termination module. The example apparatus also includes a first control module separate from the first termination module to be inserted in a first control slot of the base rack. The first control module is to be communicatively coupled with the first termination module via a backplane of the base rack. The first control module is to control communications with the field device.

Abstract: Methods and apparatus to implement communications via a remote terminal unit are disclosed. An example apparatus includes a first central processing unit module to be in communication with a host of a process control system. The example apparatus also includes a first rack including a backplane and a plurality of slots. The plurality of slots includes a master slot to receive the first central processing unit module. The backplane communicatively couples the first central processing unit module to at least one of a first communication module or a first input/output (I/O) module inserted in a second one of the slots. The backplane includes a first communication bus for communication of I/O data and a second communication bus for communication of at least one of maintenance data, pass-through data, product information data, archival data, diagnostic data, or setup data. The first communication bus is independent of the second communication bus.

Abstract: Methods and apparatus to implement communications via a remote terminal unit are disclosed. An example apparatus includes a first central processing unit module to be in communication with a host of a process control system. The example apparatus also includes a first rack including a backplane and a plurality of slots. The plurality of slots includes a master slot to receive the first central processing unit module. The backplane communicatively couples the first central processing unit module to at least one of a first communication module or a first input/output (I/O) module inserted in a second one of the slots. The backplane includes a first communication bus for communication of I/O data and a second communication bus for communication of at least one of maintenance data, pass-through data, product information data, archival data, diagnostic data, or setup data. The first communication bus is independent of the second communication bus.

Abstract: Methods and apparatus to communicatively coupled field devices to a remote terminal unit are disclosed. The example apparatus includes a base rack for a remote terminal unit in a process control system. The example apparatus further includes a first termination module to be inserted in a first termination slot of the base rack. Wires communicatively coupled to a field device are to be terminated on the first termination module. The example apparatus also includes a first control module separate from the first termination module to be inserted in a first control slot of the base rack. The first control module is to be communicatively coupled with the first termination module via a backplane of the base rack. The first control module is to control communications with the field device.

Abstract: Methods and apparatus to implement a remote terminal unit network are disclosed. An example method involves allocating, via a processor of a first remote terminal unit, a first time slot of a first frame of a first transmission schedule to the first remote terminal unit, the first remote terminal unit to be in communication with a second remote terminal unit in a network associated with a process control system and to be in communication with a host of the process control system, the first remote terminal unit to communicate first data over the network during the first time slot, and allocating, via the processor, a second time slot of the first frame to the second remote terminal unit, the second remote terminal unit to communicate second data over the network during the second time slot.

Abstract: Flow computers having wireless communication protocol interfaces and related methods are disclosed. In one example, a method involves receiving a request to be sent to a wireless device in a network of wireless devices, the request to be received via a remote terminal unit application executed on a processor within a flow computer, and communicating the request to the wireless device via a communications interface module, the communications interface module to be communicatively coupled to the processor via a backplane contained within a housing of the flow computer, the backplane to provide communications according to a high speed data bus communications protocol.

Abstract: Methods and apparatus to implement a remote terminal unit network are disclosed. An example method involves allocating, via a processor of a first remote terminal unit, a first time slot of a first frame of a first transmission schedule to the first remote terminal unit, the first remote terminal unit to be in communication with a second remote terminal unit in a network associated with a process control system and to be in communication with a host of the process control system, the first remote terminal unit to communicate first data over the network during the first time slot, and allocating, via the processor, a second time slot of the first frame to the second remote terminal unit, the second remote terminal unit to communicate second data over the network during the second time slot.

Abstract: Flow computers having wireless communication protocol interfaces and related methods are disclosed. In one example, a method involves receiving a request to be sent to a wireless device in a network of wireless devices, the request to be received via a remote terminal unit application executed on a processor within a flow computer, and communicating the request to the wireless device via a communications interface module, the communications interface module to be communicatively coupled to the processor via a backplane contained within a housing of the flow computer, the backplane to provide communications according to a high speed data bus communications protocol.

Abstract: A reporting regulator for use in a gas transportation system includes an electrical interconnection that couples a plurality of input ports to a processor and a memory. Sensor data is received at the input ports and the data is stored into the memory. The reporting regulator is assigned a unique identification number such as a MAC address. The reporting regulator marks the received sensor data with attributes such as an identification number, a time stamp or a date stamp. After marking the data, the data is transmitted to a database location. The marked data can be reassembled in time and space by a central computer using the attributes. A processor can utilize this data to monitor, characterize and control an entire gas transportation system. System events can be pinpointed in time and space using the marked data. Further, system characterization and performance metrics can be utilized to improve system efficiency, emergency management, scheduling of preventive maintenance, and billing methods.

Abstract: An in-line gas flow rate sensor includes a movable flow orifice and a fixed flow restrictor adjacent the flow orifice for changing the gas flow through the flow orifice. The flow orifice and the flow restrictor are formed so that each uniform increment of flow orifice movement provides a constant percent of flow change through the flow orifice. A magnet fixed to the movable flow orifice provides changing magnetic flux corresponding to each uniform increment of flow restrictor movement. A magnetic flux sensor responds to the changing magnetic flux and provides an output corresponding to a constant percent of flow rate changes.

Abstract: A reporting regulator for use in a gas transportation system includes an electrical interconnection that couples a plurality of input ports to a processor and a memory. Sensor data is received at the input ports and the data is stored into the memory. The reporting regulator is assigned a unique identification number such as a MAC address. The reporting regulator marks the received sensor data with attributes such as an identification number, a time stamp or a date stamp. After marking the data, the data is transmitted to a database location. The marked data can be reassembled in time and space by a central computer using the attributes. A processor can utilize this data to monitor, characterize and control an entire gas transportation system. System events can be pinpointed in time and space using the marked data. Further, system characterization and performance metrics can be utilized to improve system efficiency, emergency management, scheduling of preventive maintenance, and billing methods.

Abstract: An in-line gas flow rate sensor includes a movable flow orifice and a fixed flow restrictor adjacent the flow orifice for changing the gas flow through the flow orifice. The flow orifice and the flow restrictor are formed so that each uniform increment of flow orifice movement provides a constant percent of flow change through the flow orifice. A magnet fixed to the movable flow orifice provides changing magnetic flux corresponding to each uniform increment of flow restrictor movement. A magnetic flux sensor responds to the changing magnetic flux and provides an output corresponding to a constant percent of flow rate changes.