turck blog

Foundation Fieldbus Overview

TURCK 6/6/2018
What is it?
 
FOUNDATION fieldbus is an all-digital, serial, two-way communications system for use in applications using basic and advanced regulatory control.
 
What are its basic components?
 
H1 fieldbus interface card, fieldbus power supply and signal conditioner, bulk power (Vdc) to fieldbus power supply, terminator and fieldbus devices.
 
Where is it used?
 
Plant automation, factory automation, basic and advanced regulatory control, discrete control, process industries, power plants.
 
Who is responsible for it?
 
FOUNDATION fieldbus is an open architecture, developed and administered by the Fieldbus Foundation.
 
Overview
 
FOUNDATION Fieldbus is an all-digital, serial, two-way communications system for use in applications using basic and advanced regulatory control. TURCK’s diagnostic power conditioner (DPC) system stores and monitors information concerning the components of the control system and field devices. Information on assets that make up the communication infrastructure (physical layer components) have been simply stored in an asset management system. With the DPC system, the physical layer components are continuously monitored providing virtually instantaneous information regarding the quality and the status of the communication link. This aspect of the system is the key to achieving the main objective of asset management to minimize maintenance and lower system operating costs.
 
TURCK Foundation Fieldbus
 
Basic Parts List
 
A typical system consists of the following parts:
• Power supply
• Diagnostic power conditioner
• Junction bricks
• Fieldbus devices
 
System Configuration
 
TURCK has drastically improved on existing physical layer components for use in FOUNDATION fieldbus applications. The introduction of the DPC system allows the continuous monitoring of every physical layer component, thus treating the entire physical layer as an asset and providing the means for it to be managed as such.
 
TURCK Foundation Fieldbus
 
The DPC System detects errors that may develop over an extended period of time or through typical failure modes. These changes can occur due to many factors, such as environmental changes, deterioration of components over time and any other factors that may affect the physical components of a fieldbus segment. Some of these factors may appear as changes in jitter, hum, noise levels etc. Alarm strategies may be employed that will warn of typical asset errors, potential errors or failures. Preventive measures can be implemented well in advance of a potential system failure. Most common failures can be completely avoided when a preventive maintenance schedule is implemented.
 
The DPC system also supports the set-up of fieldbus assets by using expedient localization of error sources, as well as documentation indicating a “good condition” of the segment structure. The DPC system provides an option for redundant segment supplies. The system, fully loaded, can accommodate up to 16 fully redundant FOUNDATION fieldbus segments each with an output of 800 mA and 30 VDC. Diagnostic date is available via a DTM, standard FOUNDATION fieldbus function block libraries or an embedded web server in the HSE field device.
 
Conventional Control System
 
In a traditional control system, I/O devices in the field are individually wired to a central controller, which is responsible for all control function processing in the system. This type of system typically consumes a lot of physical space (due to the amount of wire and the number of I/O cards in the PLC or DCS) and requires a lot of design and labor to install. Additionally, finding errors in this kind of system can be very time consuming because of the number of possible error points (each physical wire termination).
 
TURCK Foundation Fieldbus
 
FOUNDATION Fieldbus System
 
In the fieldbus system, the I/O devices are wired to a trunk line (segment) using tee connectors or multi-drop boxes. Rather than separate pairs of wires carrying data to and from each I/O device, the devices use a common pair of wires for communication, with each having a turn to “talk” on the network. Instead of performing all the control functions in the host, the FOUNDATION fieldbus system allows for control blocks to be executed in the field devices themselves, creating an efficient, high integrity system. One device on the network is responsible for scheduling communication between the various devices on the system. This is called the Link Active Scheduler (LAS). It can be the host interface or a device in the field.
 
In most FOUNDATION fieldbus systems at least one backup LAS is defined as well. This allows communication and control to continue in case the original LAS device fails. Most FOUNDATION fieldbus devices are powered completely from the network supply. In some cases a device may draw enough current to make it impractical to power it from the network.
 
In these cases the device is typically powered from a separate (auxiliary) supply. Another key benefit of using FOUNDATION fieldbus is the ease of adding I/O devices to the system in the future. Because it is a serial bus where all devices use the same wires for communication, a device can be added by simply splicing it onto the network. This eliminates the need to pull a new wire pair all the way back to the controller. FOUNDATION fieldbus devices also typically include a multitude of parameters and diagnostic information, all accessible over the network. Advanced diagnostics and maintenance scheduling are made much easier with this feature.
 
TURCK Foundation Fieldbus
 
Communication Signal
 
The FOUNDATION fieldbus H1 communication signal is a square waveform superimposed on a DC carrier. The frequency of the signal is 31.25 Khz. Although it is not a requirement, most devices derive their supply power from the fieldbus communications cable. The fieldbus specification states that devices must not be polarity sensitive. However, it is good electrical practice to have all devices wired with the same polarities. The voltage range allowed for proper operation is 9 to 32 VDC. A typical fieldbus device will consume 20 mA of current.
 
TURCK Foundation Fieldbus
 
Fieldbus Cable Specifications
 
The specifications for fieldbus H1 physical media are defined by IEC 61158-2 and the ISA-S50.02 Part 2 Physical Layer Standards. The same standard is also listed in the FOUNDATION fieldbus specifications under 31.25 Kbps Physical Layer Profile FF-816-1.4. There are essentially four types of cable designations for fieldbus. Type A cable preferred for new installations, because it allows for the most versatile lengths. The other cable types are for installations where cable already exists from 4-20 mA systems. See table 1.
 
TYPE CABLE DESCRIPTIONS CONDUCTOR SIZE MAXIMUM LENGTH
Type A Shielded, Twisted Pair 18 AWG 1900 m (6232 ft)
Type B Shielded, Multi Twisted Pair 22 AWG 1200 m (3936 ft)
Type C Unshielded, Multi Twisted Pair 26 AWG 400 m (1312 ft)
Type D Shielded, Untwisted Pair 16 AWG 200 m (656 ft)
 
TURCK Foundation Fieldbus
 
TURCK offers type A cables with both two conductors and three conductors, with the third conductor available for a centralized ground of devices if needed. TURCK cables meet or exceed the specifications of ANSI/ISA-SP50.02-1992, the fieldbus standard for use in industrial control systems. The maximum spur length is determined by the number of devices in the segment.
 
CABLE NUMBER OF DEVICES MAXIMUM SPUR LENGTH
Trunk 25-32 0 m (0 ft)
Trunk 19-24 30 m (98 ft)
Trunk 15-18 60 m (197 ft)
1900 Meters 15-18 60 m (197 ft)
1900 Meters 13-14 90 m (295 ft)
1900 Meters 2-12 120 m (394 ft)
 
Termination
 
The FOUNDATION fieldbus communication signal requires that each end of the system be terminated with a 1 µF capacitor in series with a 100 W resistor across the communication lines. This termination must be installed at each extreme end of the network segment. Do not use more than two terminators on a communication segment.
 
Hazardous Area Usage
 
FOUNDATION fieldbus networks may be used in hazardous areas as long as required energy limitations for the specific area are observed. One way to achieve this is to use the “entity” concept, which requires the network designer to calculate the voltage and current requirements for each device and determine the system limitations. A simpler option is to use the Fieldbus Intrinsic Safety Concept (FISCO) or Fieldbus Non-Incendive Concept (FNICO). These concepts define the limitations required for devices on a network system to be used in a hazardous area (Class I, Div 1 for FISCO and Class I, Div 2 for FNICO). Many newer FOUNDATION fieldbus devices are rated to meet the requirements of FISCO and/or FNICO. As long as the devices used and the power supply are marked with FISCO or FNICO they may be connected together in the appropriate hazardous area. It is important to note that the cabling used must still meet the defined parameters.
 
Using Connectorization
 
Plug-and-play connectorization has been standard practice for many years in industries ranging from appliance manufacturers to industrial sensors. These industries have found it necessary to compete in a business climate where speed and consistency of connection is king. Connectorization is the perfect complement to fieldbus systems. The concepts and goals are identical: reduce installation time, reduce troubleshooting and easy expansion. The fieldbus system minimizes point-to-point wiring that can be time-consuming and difficult to troubleshoot. Connectorization takes that one step further, almost completely eliminating troubleshooting. Plants that have implemented plug-and play connectorization claim up to a 75 percent reduction in start-up. This directly translates into real cost savings.
 
Cost Savings
 
The initial capital cost is the major factor in selecting a method of connecting devices. These costs include material and installation. The cost of incorporating plug-and-play connectivity will be 10 to 60 percent less. Actual savings will depend on the size and complexity of the installation. Other cost saving factors include reduced design cost, reduced maintenance cost, reduced troubleshooting cost and reduced expansion costs. Some of these cost savings are difficult to determine until the condition exists. However, these costs can quickly change from potential cost savings to real cost savings when the installation begins.
 
Design Cost Savings
 
Most projects begin with a rough definition to develop the capital scope and then progress to detailed development. Development of the capital scope is often expressed in terms of segments, transmitters and tanks. The cabling can be expressed in the same way. Each transmitter requires one device gland and one cordset. Each tank requires one tee, one drop cordset and typically one brick. The home run or trunk cable can run in either conduit or cable tray, so either a field wireable tee or a conduit adapter is required at each tank. A terminating resistor is needed at the beginning and end of the network. A simple estimated bill of materials can be developed as follows: For: 4 segments, 50 transmitters, 10 tank process.
 
DESCRIPTION PRODUCT NUMBER QUANTITY
Device Glands RSFV 49-0.3M/14.5 50
Cordsets RSV RKV 490-6M 60 (50 Transmitters + 10 Drops)
Multiport Bricks JBBS-49SC-M613 10
Field Wireable Tee SPTT1-A49 10
Terminating Resistor RSV-49-TR 8
Bulk Cable CABLE, 490-300M 1
 
Often for estimating purposes, an average length of cordset and segment length is assumed. In this example, 6 m (20 ft.) cordsets and four 75 m (250 ft.) segments are estimated. The cost and time of coping with continuous changes during the engineering design phase can be very expensive. However, with this model the changes are limited to the length of the cordset and spool of bulk cable. Design changes can even wait until all the transmitters are mounted. Simply taking physical measurements is as valid as any other design method.
 
Material Costs
 
The cost of cordsets and bricks will be slightly lower than the cost of termination in enclosures. The plug-and-play junction bricks are IP67 rated (equivalent NEMA 4X). This means they can be mounted indoors or outdoors without any secondary enclosures. A NEMA 4X enclosure can cost anywhere from $75 for steel to $275 for stainless steel. The cost can increase by another $40 to $60 for the design and installation time required to put mounting holes in the enclosure and installing cable glands. A cage clamp style termination block costs $200 to $450 depending on whether is has short circuit protection. The plug-and-play bricks cost only $322 and $486 depending on whether they have short circuit protection. A set of six cordsets costs only $264 (RSV RKV 490-1M)*. The material cost comparison for a stainless steel installation is as follows:
 
FIELD WIRING *Est. Cost
NEMA 4X box (Hoffman or equivalent) $ 275
Cage clamp termination block 450
Installation of blocks in box 50
Bulk cable (6 meters) 12
Device gland (1/2 NPT fitting = $8.00) 48
TOTAL $ 835
PLUG AND PLAY *Est. Cost
Junction brick (JBBS-49SC-M613) $ 486
Cordsets (six RSV RKV 490-1M = $44.00) 264
Device gland (RSFV 49-0.3M/14.5 = $30.30) 181
TOTAL $ 931
 
A junction brick system that is completely encapsulated for use indoors or outdoors is equivalent to or approximately 10 percent more expensive than a termination block mounted in an enclosure. The real savings are in the speed and ease of installation.
 
* Costs given are examples only, and are subject to change.