CAN Newsletter June 2009
| Business | Vacon in South Korea - Baumueller in India 6 ESP saves lives and is mandatory in Europe 8 NEC and Renesas - Vector subsidiary in UK 10 Comment - Bombardier and B&R - Medical devices 12 Eaton and Moeller 19 Books 53 |
|---|---|
| Device | Data acquisition system - HMI and control platform 10 Single-axis servo converter - Embedded 26 CAN control systems 31 Servo motor - I/O system - Vehicle computer - HMI 36 CAN-to-Ethernet gateways and interface cards 47 Controller - CAN transceiver 49 Energy efficiency in motion control 56 Pneumatic module - For harsh and long-term applications 63 Correction - Periphery - Inclinometer - Oscilloscope 64 |
| Application | Automation system for rail diesel engines 14 Robot-hand - Process engineering 16 KERS and start/stop: Saving energy is the challenge 20 CAN connects peripherals of model railway controller 34 Flexible robot solutions with CAN 50 CANopen in cross-table for microscopes 51 Field-bus networking solution 52 |
| Semiconductor | For automotive - For safety-critical applications 18 Automotive ECUs become “green” 22 For safety applications - Autosar collaboration 32 |
| Tools | Creating ODX data - Tool for Codesys - CANopen kit 38 |
| Software | Code generation - Engineering - Linux - J1939 48 |
| Revision course | Device type parameter in CANopen 54 |
| Dossier | Intrinsically safe CAN communication 60 |
| Reader service | CAN Newsletter subscription form 66 |
| Supplement | Omron selects Ethercat - Award - Industrial Ethernet 1 Powerlink in packaging machines - Frequency inverter 2 ETG develops safety drive profile - Ethercat servo drive 3 Control panel - CiA 402 test tool - Motion control 4 Modular drive system - Ethercat servo amplifiers 5 Real-time Ethercat master - Embedded PC - Ethercat tools 6 |
- Fig. 1: Working on one of the 748 nodes
Comment - Olympic rings use large CAN network
Beginning of March, Canada’s Premier Gordon Campbell has lighted up the 14-m tall Olympic Rings that will greet travelers at Vancouver International Airport. The rings and its control system were designed and built by several high-tech companies using high-efficiency LEDs. The single network connecting 748 nodes is one of the largest if not the largest CAN network. The CAN-IDs are reconfigured dynamically, which regroups the LED nodes, so that they can receive in multicast the lighting commands.
Unfortunately, it is not allowed to name the parties involved in this project, because they are not Olympics sponsoring companies! It seems that the International Olympic Committee (IOC) has come down hard on the company that managed the project for mentioning on their website that they built the lights for the rings. There is a rumor that General Electric (an Olympic Sponsor) is upset that they didn’t get to do the lights. So if more rings are built, they may just be mono-colored with white GE low-power light.
Five-finger robot-hand with CAN
Based on the technique of DLR-Hand II, HIT (Harbin Institute of Technology in China) and DLR (German Aerospace Center) department for robotics and mechatronics developed a smaller, multi-sensor robot-hand called DLR-HIT-Hand II. The robot-hand features five fingers with four finger joints each. Each finger has three degrees of freedom: It may be moved forward and backward (1st joint), to the left and right (2nd joint) and be extracted/retracted (3rd and 4th joints). The available on the market brushless DC motors with analog Hall sensors (for commutation) are used as drives. The motors are integrated in the fingers and in the carpus (wrist) of the hand. Each joint is equipped with an angle sensor and a strain gauge-based torque sensor.
The complete hand is controlled via a signal-processor, previously mounted on a PCI plug-in card. Using optimized control functions and more powerful signal-processors, it is now possible to embed the complete control on a PCB (printed circuit board) into the hand. Therewith the amount of communicated data was reduced and interconnection of devices via CAN was realized in a prototype solution.
Several institutes worldwide required development of the five-finger hand. With the new hand an important impulse shall be given for the service-robotics applications – one of the most important future markets.
This information was provided by Peter Meusel from DLR.
Intrinsically safe CAN communication
- Fig. 1: The PGC 5000 system uses for the sample handling device as well as the ovens CiA 103 compliant networks; for the connection to the host controller fiber optical cables are used
How it all started
Some years ago, some members of NeSSI (New Sampling/Sensor Initiative) requested an intrinsically safe CAN physical layer in order to connect dedicated sensors in explosive environments. The initiative is sponsored by the Center for Process Analytical Technology (CPAC) at the University of Washington in Seattle (WA). The initiative’s objectives include simplification of tasks and reduction of overall costs associated with engineering, installing and maintaining chemical process analytical systems. The specific objectives are to increase process analytical system reliability through the use of increased automation, shrink the physical size (and energy use) by means of miniaturization, promote the creation and use of industry standards for process analytical systems, and help create the infrastructure needed to support the use of the emerging class of robust and selective microanalytical sensors. Process analytical systems are commonly used by the chemical, oil refining and petrochemical industries to measure and control both chemical composition as well as certain intrinsic physical properties (such as viscosity). To date, NeSSI has served as a forum for the adoption and improvement of an industrial standard, which specifies the use of miniature and modular Lego-like flow components. Circor Tech, Parker-Hannifin, and Swagelok develop and produce such components.
To control those flow components electronically requires a communication system. One of the candidates was CAN. In the beginning, NIST (National Institute of Standards and Technology) located in Washington (DC) organized some meetings and started the specification under the umbrella of IEEE. CiA submitted its CANopen profile for measuring devices and closed-loop controllers (CiA 404). However, the IEEE 1451‑6 standard never comes out of its shoes. After about three years, CiA was requested to take over the development of an intrinsically safe CAN physical layer. Experts from ABB Lewisburg, Circor Tech, Parker, Pepperl + Fuchs, Siemens, Swagelok, Texas Instruments, and Turck participated in the CiA Task Force (“Intrinsically safe CAN”) meetings. The result is the CiA 103 draft standard proposal, which is more a framework than a specification or standard.
This framework provides some basic rules to design CAN physical layer interfaces suitable for intrinsic safe CAN communication. The basic idea is to use 3,3‑V powered CAN transceiver (ISO 11898-2) and CAN micro-controllers. In addition, some circuitry may be necessary to make the interface intrinsic safe (IS) – in particular to implement an isolation barrier between safe and hazardous area. The specification is downloadable from CiA’s members’ website. CiA 103 recommends an 8-pin pico-style connector with a standardized pin-assignment.
IS-CANopen based on CiA 103 has become the NeSSI bus solution envisioned nearly six years ago. The NeSSI consortium has shown that a low-cost transducer bus can be intrinsically safe. CiA device profiles and CANopen conformance testing furnish the infrastructure by which transducer vendors can offer certified plug-and-play multi-channel devices for cost-effective sensor and actuator solutions. CiA also provides a forum for SIGs (special interest groups), such as NeSSI, to adjust the CANopen profiles to meet their specific industry requirements.
First CiA 103 applications
The market for sample-handling systems or process gas chromatographs is a worldwide business. In former times, they were not electronically controlled. The permanent increasing demand to improve sample-handling system leads to highly complex user interfaces. In order to simplify the operating interface, classic text-oriented displays are substituted by graphic user-terminals. The PGC 5000 series by ABB links up to four analyzer ovens to the master control unit, which also provides the graphical user interface. Circor Tech supplies some of the CANopen flow components, which have been exclusively developed for ABB.
In addition Circor Tech provides the DMT series of multi-variable flowmeters, which are able to measure simultaneously upstream and downstream pressure, fluid temperature, and flow rate for liquids or gases. Unlike conventional low-flow meters, such as thermal mass flow devices, the DMT flowmeters provide multi-variable measurement data and control through the CANopen interface. They also offer IP65 and NEMA4x protection. They are the first components of its kind to provide full multi-variable measurement and closed-loop control in a Class 1, Division 1 hazardous area, without requiring explosion-proof conduits and enclosures. Circor Tech use IS-CAN (CiA 103) also for its DVM valve manifold and its CIM76 module, which bridges the link between an IS‑CAN network and a non-IS industrial Ethernet network. The CAN and CANopen interfaces have been developed with the support of ESAcademy, HMS, Ixxat, Peak Systems, Pepperl + Fuchs, Siemens, and Turck as well as others. Several national authorities have already certified the products.
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