Smartwire-DT Gateways – Canopen and PROFIBUS-DP

Total Page:16

File Type:pdf, Size:1020Kb

Smartwire-DT Gateways – Canopen and PROFIBUS-DP 09/11 MN05013002Z-EN Manual replaces 06/09 AWB2723-1612en SmartWire-DT Gateways All brand and product names are trademarks or registered trademarks of the owner concerned. Emergency On Call Service Please call your local representative: http://www.eaton.com/moeller/aftersales or Hotline of the After Sales Service: +49 (0) 180 5 223822 (de, en) [email protected] Original Operating Instructions The German-language edition of this document is the original operating manual. Translation of the original operating manual ) All editions of this document other than those in German language are translations of 2 the original German manual. 1st edition 2009, edition date 02/09 2nd edition 2009, edition date 06/09 3rd edition 2010, edition date 03/10 4th edition 2010, edition date 06/10 5th edition 2011, edition date 03/11 6th edition 2011, edition date 09/11 See revision protocol in the “About this manual“ chapter © 2009 by Eaton Industries GmbH, 53105 Bonn Production: René Wiegand Translation: globaldocs GmbH All rights reserved, including those of the translation. Rückenbreite festlegen! (1 Blatt = 0,106 mm, gilt nur für XBS) g/m 80 bei Digitaldruck Eberwein für mm = 0,080 Blatt (1 No part of this manual may be reproduced in any form (printed, photocopy, microfilm or any other process) or processed, duplicated or distributed by means of electronic systems without written permission of Eaton Industries GmbH, Bonn. Subject to alteration without notice. Danger! Dangerous electrical voltage! Before commencing the installation • Disconnect the power supply of the • Suitable safety hardware and device. software measures should be • Ensure that devices cannot be implemented for the I/O interface accidentally restarted. so that a line or wire breakage on the signal side does not result in • Verify isolation from the supply. undefined states in the automation • Earth and short circuit. devices. • Cover or enclose neighbouring units • Ensure a reliable electrical isolation that are live. of the low voltage for the 24 volt • Follow the engineering instructions supply. Only use power supply units IL (previously AWA) of the device complying with IEC 60364-4-41 concerned. (VDE 0100 Part 410) or HD 384.4.41 S2. • Only suitably qualified personnel in accordance with EN 50110-1/-2 • Deviations of the mains voltage (VDE 0105 Part 100) may work on from the rated value must not this device/system. exceed the tolerance limits given in the specifications, otherwise this • Before installation and before may cause malfunction and touching the device ensure that you dangerous operation. are free of electrostatic charge. • Emergency stop devices complying • The functional earth (FE) must be with IEC/EN 60204-1 must be connected to the protective earth effective in all operating modes of (PE) or to the potential equalisation. the automation devices. Unlatching The system installer is responsible the emergency-stop devices must for implementing this connection. not cause restart. • Connecting cables and signal lines • Devices that are designed for should be installed so that inductive mounting in housings or control or capacitive interference does not cabinets must only be operated and impair the automation functions. controlled after they have been • Install automation devices and installed with the housing closed. related operating elements in such Desktop or portable units must only a way that they are well protected be operated and controlled in against unintentional operation. enclosed housings. Eaton Industries GmbH Industries Eaton Safety instructions I • Measures should be taken to • Wherever faults in the automation ensure the proper restart of system may cause damage to programs interrupted after a voltage persons or property, external dip or failure. This should not cause measures must be implemented to dangerous operating states even ensure a safe operating state in the for a short time. If necessary, event of a fault or malfunction (for emergency-stop devices should be example, by means of separate implemented. limit switches, mechanical interlocks etc.). II Contents Contents 0 About This Manual..................................................................... 5 0.1 List of revisions ............................................................................ 5 0.2 Overview SmartWire-DT .............................................................. 6 0.3 Further information on the device................................................ 6 0.4 Target group................................................................................. 7 0.5 Writing conventions ..................................................................... 7 0.5.1 Hazard warnings of material damages ......................................... 7 0.5.2 Hazard warnings of personal injury .............................................. 7 0.5.3 Tips............................................................................................... 7 1 PROFIBUS Gateway EU5C-SWD-DP......................................... 9 1.1 Introduction .................................................................................. 9 1.2 surface mounting ......................................................................... 9 1.3 Engineering .................................................................................. 10 1.3.1 Connection................................................................................... 10 1.3.2 PROFIBUS address setting .......................................................... 12 1.3.3 PROFIBUS connection ................................................................. 12 1.3.4 Baud rate...................................................................................... 12 1.3.5 Device master data (GSD)............................................................ 12 1.3.6 Diagnostics interface.................................................................... 13 1.4 Installation .................................................................................... 14 1.4.1 Mounting...................................................................................... 14 1.4.2 Connection SmartWire-DT ........................................................... 16 1.4.3 PROFIBUS-DP connection ........................................................... 16 1.4.4 EMC-conformant wiring of the network ...................................... 17 1.5 Commissioning ............................................................................ 18 1.5.1 Putting the SmartWire-DT network into operation....................... 18 1.6 Programming................................................................................ 21 1.6.1 Introduction .................................................................................. 21 1.6.2 Configuration and parameterization with CoDeSys...................... 22 1.6.3 Acyclic data communication......................................................... 28 1.6.4 Configuration and Parameterization with STEP 7......................... 31 1.6.5 Acyclical data communication ...................................................... 42 1.6.6 Diagnostics................................................................................... 42 1.6.7 Device-specific diagnostics .......................................................... 45 2 CANOpen gateway EU5C-SWD-CAN ....................................... 47 2.1 Introduction .................................................................................. 47 2.2 Setup............................................................................................ 47 2.3 Engineering .................................................................................. 48 2.3.1 Connection................................................................................... 48 2.3.2 CANopen address setting ............................................................ 50 2.3.3 CANopen connection ................................................................... 50 2.3.4 Baud rate...................................................................................... 50 2.3.5 Description file (EDS) ................................................................... 50 2.3.6 Diagnostics interface.................................................................... 51 2.4 Installation .................................................................................... 52 2.4.1 Mounting...................................................................................... 52 SmartWire-DT Gateways 09/11 MN05013002Z-EN www.eaton.com 1 Contents 2.4.2 Connection SmartWire-DT........................................................... 54 2.4.3 Connection CANopen .................................................................. 54 2.4.4 EMC-conformant wiring of the network ...................................... 55 2.5 Commissioning ............................................................................ 56 2.5.1 Introduction.................................................................................. 56 2.5.2 Putting the SmartWire-DT network into operation ...................... 56 2.6 Programming ............................................................................... 60 2.6.1 Introduction.................................................................................. 60 2.6.2 Configuration and parameterization with CoDeSys ..................... 61 2.6.3 Diagnostics .................................................................................. 68 2.6.4 Object directory ..........................................................................
Recommended publications
  • — PROFIBUS-Adapter
    — ABB MEASUREMENT & ANALYTICS | DATA SHEET PROFIBUS-Adapter — To find your local ABB contact visit: www.abb.com/contacts For more information visit: www.abb.com/measurement — We reserve the right to make technical changes or modify the contents of this document without prior notice. With regard to purchase orders, the agreed particulars shall prevail. ABB does not accept any responsibility whatsoever for potential errors or possible lack of information in this document. We reserve all rights in this document and in the subject matter and illustrations contained therein. Any reproduction, disclosure to third parties or utilization of its contents – in whole or in parts – is forbidden without prior written consent of ABB. © ABB 2019 3KXN631121R1001 10/63-6.31-EN Rev. G 05.2019 2 NDA121-NO PROFIBUS-ADAPTER | 10/63-6.31-EN REV. G NDA121-NO PROFIBUS-ADAPTER | 10/63-6.31-EN REV. G 7 — Measurement made easy — Profibus DP / PC Adapter • USB NDA121-NO PROFIBUS-ADAPTER | 10/63-6.31-EN REV. G 3 — NDA121-NO PROFIBUS DP / PC-USB adapter hange from one to two columns Adapter CommDTM Desktop PC’s as well as notebooks can be flexible connected The Device Type Manager CommDTM provides access to the in the field to a PROFIBUS® network via the adapter PROFIBUS® Master NDA121-NO. Within the FDT architecture, NDA121-NO. Thereby a parallel operation of up to 16 adapter the CommunicationDTM enables DeviceDTMs to connect to is possible. The adapter supports the Master functionality of their respective devices via PROFIBUS® DP/-V1. the PROFIBUS® Standards DP (class 1 and 2), DP-V1 (class 2).
    [Show full text]
  • Master Simulators
    Master simulators By using master simulators from HMS, you can set up and test slaves/adapters on PROFIBUS, PROFINET, CANopen, EtherNet/IP and DeviceNet without having a PLC in place. Simply connect to your computer and you have a very cost-efficient alternative to a PLC or PC-card. CANopen interface — powered by USB USB port on the PC RS-232 CANopen cable 9-pin D-Sub connector PROFIBUS interface Device under test Device under test DeviceNet interface USB (24V power supply required to connect and test a DeviceNet adapter —not included). DeviceNet cable with data and power lines Pluggable screw connector Ethernet cable with termination Device under test Device under test Available for: Test your device without an expensive PLC Key features Master simulators are ideal for test-wiring of inputs and ouputs • Easy-to-use test and diagnostics and reading and writing analog values. They are useful during tool. setup of slave/adapters in a network as well as during final • No programming required. inspection tests at the device manufacturer. • Auto-detects slaves/adapters Industrial Ethernet versions are software-only, while fieldbus (even when GSD/EDS file is not versions also include a converter interface which is used to available). connect the fieldbus cable to the PC. • Auto detection of I/O data size. No GSD/EDS files needed (not for EtherNet/IP) During setup and maintenance, there may not be GSD/EDS available making master simulators especially useful for this scenario. HMS provides a full 3 year product guarantee TECHNICAL SPECIFICATIONS Description Consists of a Windows-based Software only.
    [Show full text]
  • The Role of CAN in the Age of Ethernet and IOT
    iCC 2017 CAN in Automation The role of CAN in the age of Ethernet and IOT Christian Schlegel, HMS Industrial Networks CAN technology was developed in the 1980s and became available in 1987, just as other industrial fieldbus systems like PROFIBUS or INTERBUS entered the stage of industrial communication. Beside the fact that CAN is a success in the automotive industry and used in all types of cars today, it has also made its way in many other industrial areas. About 15 years ago, new technologies based on Ethernet started to emerge, with ap- pealing and sometimes outstanding features. Some six years ago Ethernet also started to find its way into automobiles. Today, other new communication technologies are showing up on the horizon driven by the omnipresent Industrial Internet of Things. But even now, 30 years after their introduction, these “classic” fieldbus technologies are still alive – with varying success. Since CAN was initially developed with a focus for use in automobiles, CAN has certain features that still make it the best choice for many applications in automobiles and industrial areas – even when compared to the newer technologies. This paper discusses why CAN is still a valid or even better choice for certain applica- tion areas than Ethernet-based technologies, not just focusing on the advanced fea- tures provided by the enhanced capabilities of CAN FD but also highlighting how these applications benefit from the features of “classic” CAN. Looking back into history … the requirement to transmit data between … when CAN was born these ECUs but also to connect sensors and actuators to them.
    [Show full text]
  • Fieldbus Communication: Industry Requirements and Future Projection
    MÄLARDALEN UNIVERSITY SCHOOL OF INNOVATION, DESIGN AND ENGINEERING VÄSTERÅS, SWEDEN Thesis for the Degree of Bachelor of Science in Engineering - Computer Network Engineering | 15.0 hp | DVA333 FIELDBUS COMMUNICATION: INDUSTRY REQUIREMENTS AND FUTURE PROJECTION Erik Viking Niklasson [email protected] Examiner: Mats Björkman Mälardalen University, Västerås, Sweden Supervisor: Elisabeth Uhlemann Mälardalen University, Västerås, Sweden 2019-09-04 Erik Viking Niklasson Fieldbus Communication: Industry Requirements and Future Projection Abstract Fieldbuses are defined as a family of communication media specified for industrial applications. They usually interconnect embedded systems. Embedded systems exist everywhere in the modern world, they are included in simple personal technology as well as the most advanced spaceships. They aid in producing a specific task, often with the purpose to generate a greater system functionality. These kinds of implementations put high demands on the communication media. For a medium to be applicable for use in embedded systems, it has to reach certain requirements. Systems in industry practice react on real-time events or depend on consistent timing. All kinds are time sensitive in their way. Failing to complete a task could lead to irritation in slow monitoring tasks, or catastrophic events in failing nuclear reactors. Fieldbuses are optimized for this usage. This thesis aims to research fieldbus theory and connect it to industry practice. Through interviews, requirements put on industry are explored and utilization of specific types of fieldbuses assessed. Based on the interviews, guidelines are put forward into what fieldbus techniques are relevant to study in preparation for future work in the field. A discussion is held, analysing trends in, and synergy between, state of the art and the state of practice.
    [Show full text]
  • Profibus and Modbus: a Comparison
    James Powell, P. Eng. Profibus and Modbus: a comparison We live in a multi-protocol In this article, we will provide an overview col that only Modicon could use. However, of both protocols and discuss their key it was later published royalty-free so that world – and this will likely strengths and applications. Comparing the anyone could use it. Finally, Modicon made not change anytime soon. two, we’ll see that both protocols have their it an open protocol. When it was published, own particular strengths. We’ll also discuss a number of companies started using it, Different protocols work which one works best in which applications creating different interpretations and modi- better in different applica- – although there is some overlap in what fi cations of the original specifi cation. As a each can do. What’s more, they can com- result, there are now quite a few variations tions. I have not come to plement each other in joint applications. in the fi eld. bury Modbus or Profibus, Introduction to Modbus The specifi cation document is fewer than nor to praise them, but 100 pages in length, which is a good indica- rather to add some per- Modbus is the “granddaddy” of industrial tion of the protocol’s low level of complex- communication protocols. It was originally ity. In comparison, Profi bus’ specifi cation spective and knowledge. designed in the mid-1970s by Modicon as document is thousands of pages long. a way to link intelligent devices with PLCs using a simple master/slave concept. The term “Modbus” typically refers to one of three related protocols: Modbus ASCII, “Simple” is a key descriptor for Modbus – Modbus RTU, or Modbus TCP/IP:1 and also its biggest strength.
    [Show full text]
  • Table of Contents
    Table of Contents Chapter 1 Bus Decode -------------------------------------------------------------- 1 Basic operation --------------------------------------------------------------------------------------------- 1 Add a Bus Decode ----------------------------------------------------------------------------------------------------- 1 Advance channel setting ---------------------------------------------------------------------------------------------- 2 Specially Bus Decode: ------------------------------------------------------------------------------------------------ 4 1-Wire ------------------------------------------------------------------------------------------------------------------- 7 3-Wire ------------------------------------------------------------------------------------------------------------------- 9 7-Segment -------------------------------------------------------------------------------------------------------------- 11 A/D Converter--------------------------------------------------------------------------------------------------------- 14 AcceleroMeter -------------------------------------------------------------------------------------------------------- 17 AD-Mux Flash -------------------------------------------------------------------------------------------------------- 19 Advanced Platform Management Link (APML) ---------------------------------------------------------------- 21 BiSS-C------------------------------------------------------------------------------------------------------------------ 23 BSD ---------------------------------------------------------------------------------------------------------------------
    [Show full text]
  • Profinet Vs Profibus
    Profinet vs Profibus Pouya Aminaie1 and Poorya Aminaie2 1Department of ECE, Shiraz University, Shiraz, Iran 2 Department of ECE, Shahid Beheshti University, Tehran, Iran E-mail: [email protected] Abstract We present a step by step definition of Profinet and Profibus. We introduced different types of each of the two communication protocols. We then described the topology and performance of each one individually. Finally, the properties of them have been compared to show that which one has better performance in the industry. Keywords: Profinet, Profibus, Industrial Ethernet and Communication Networks 1. Introduction 1.1. Profinet Profinet is the abbreviation for Process Field Net, which refers to technical standards for data communication through Ethernet in the industry. These types of standards are used for gathering data and controlling industrial equipment. As can be seen from Fig.1, Profinet satisfies all the needs of industrial technologies. Fig.1 Requirement of automation technology [1] 1 The need for Profinet is felt in production automation and processing automation sections, where its use can resolve many of these needs. Profinet can be divided into two main categories, as follows: • Profinet IO • Profinet CBA 1.2. Profibus The word Profibus is taken from the phrase Process Field Bus. The scope of this protocol covers from the field level to the control level. The advantages of Profibus are as follows: 1. Low noise acceptance due to twisted pair cable being the transmission interface. 2. Appropriate bandwidth due to the use of an appropriate transmission method such as RS485. 3. Secure and non-interfering data exchange for using the token pass access method.
    [Show full text]
  • PROFIBUS Modules with Plug-N-Play Connectivity Reduce Overall
    PROFIBUS Introduction Standardized Open Fieldbus System About Lumberg Automation PROFIBUS Products PROFIBUS (PROcess FIeld BUS) is a standardized, open Fieldbus in compliance with the To ensure the best application of PROFIBUS- international standard EN 50170. To meet DP in the decentralized sector, components PROFIBUS Modules various demands in automation technology, must meet maximum electromechanical PROFIBUS is subdivided into four different demands. Thanks to the materials used for the with Plug-N-Play profiles: housings and sealing technologies, Lumberg Automation’s PROFIBUS-DP components offer PROFIBUS-FMS (Field Message Specification) Connectivity Reduce excellent protection for electronic equipment in A protocol for communication between harsh environments. different control systems (PLCs or PCs). It Modules are available with M23 connection Overall Installation and was the first implementation of Profibus. This technology for hybrid cables (power supply and protocol is superseded by PROFInet.. Maintenance Costs. bus line in one cable) and M12 connectors with PROFINET external power supply. An Industrial Ethernet implementation of Transmission Media Profibus. PROFINET is designed to work everywhere: from communication with the • Shielded, twisted-pair, 2-wire cable corporate network over the data exchange (according to RS485) between PLC’s and IPC’s, to I/O and motion • Fiber optic cable control. • Hybrid cable for the transmission of data PROFIBUS-PA (Process Automation) and power supply. An intrinsically safe bus system for process technology. Network Topology PROFIBUS-DP (Decentral Periphery) • Line structure with active bus termination (resistance network) at both ends of a A transmission protocol for communication segment. between the control system and decentral input/output stations. • A segment is the bus sector between two terminating resistors.
    [Show full text]
  • Manual Absolute Encoder SAE J1939 (With Bus Cover)
    Manual Absolute Encoder SAE J1939 (with bus cover) 11.12 · 174.02.059/5 Subject to technical and design modifications www.baumer.com Errors and omissions excepted. Content Page 1 Introduction 3 1.1 Scope of delivery 3 1.2 Product assignment 4 2 Safety precautions and operating instructions 5 3 Product families 6 4 CAN-Bus 7 4.1 CAN-Bus 7 4.1.1 CAN bus properties 7 4.2 SAE J1939 8 4.2.1 PGN Definitions for SAE J1939 encoder 9 5 Commissioning 10 5.1 Mechanical assembly 10 5.2 Electrical connection 11 5.2.1 Attaching the bus cover 11 5.2.2 Terminal assignment 13 5.2.3 User address 13 5.2.4 Baudrate 13 5.2.5 Terminating resistor 13 6 SAE J1939 Operation 14 6.1 NAME-Field 14 6.2 PGN 65450 Cyclic Input Data 14 6.3 PGN 61184 encoder parameterization 15 6.3.1 Read parameter (read request) 15 6.3.2 Write parameter (write request) 16 6.3.3 Parameter Index Details 16 7 Diagnosis and additional information 18 7.1 Error diagnosis via fieldbus 18 7.2 Indicating elements (state indicators) 18 7.3 J1939 Glossary / Abbreviations 18 Manual_SAEJ1939_EN.docx 2/18 www.baumer.com 22.11.12 Disclaimer of liability The present manual was compiled with utmost care, errors and omissions reserved. For this reason Baumer IVO GmbH & Co. KG rejects any liability for the information compiled in the present manual. Baumer IVO nor the author will accept any liability for direct or indirect damages resulting from the use of the present information.
    [Show full text]
  • PROFIBUS the Perfect Fit for the Process Industry Technical Brochure · April 2008
    © Siemens AG 2008 PROFIBUS The perfect fit for the process industry Technical Brochure · April 2008 PROFIBUS www.siemens.com/profibus © Siemens AG 2008 Totally Integrated Automation ERP – Enterprise Resource Planning Ethernet Management Level MES – Manufacturing Execution Systems SIMATIC IT Ethernet Operations Level SIMATIC PCS 7 Process Control (DCS) Industrial Ethernet Industrial Software for • Design and Engineering • Maintenance • Installation and Commissioning • Modernization and Upgrade • Operation Control Level SINUMERIK SIMOTION SIMATIC NET SIMATIC Controllers SIMATIC HMI Computer Numeric Control Motion Control System Industrial Modular/Embedded/ Human Machine Communication PC-based Interface Field Level PROFIBUS PA AS-Interface SINAMICS Drive Systems Process Instrumentation SIMATIC Sensors SIMATIC Distributed I/O Totally HART Integrated IO-Link Automation Thanks to Totally Integrated Automation, Siemens is the only TIA is characterized by its unique continuity. provider of an integrated basis for implementation of custom- It provides maximum transparency at all levels with reduced ized automation solutions – in all industries from inbound to interfacing requirements – covering the field level, production outbound. control level, up to the corporate management level. With TIA you also profit throughout the complete life cycle of your plant – starting with the initial planning steps through operation up to modernization, where we offer a high measure of invest- ment security resulting from continuity in the further develop- ment of our products and from reducing the number of inter- faces to a minimum. 2 PROFIBUS © Siemens AG 2008 Contents text PROFIBUS PROFIBUS - an integrated fieldbus for the complete process automation . 4 Your advantages with PROFIBUS . 7 PROFIBUS - proven and future-oriented . 8 Technical basis General features and standards .
    [Show full text]
  • Travellogic Logic Analyzer
    + TL2136B TL2236B TL2236B Acute Timing Analysis (Asynchronous, Max. Sample Rate) TravelLogic logic analyzer State Clock Rate (synchronous, External Clock) Multi channel • PC-based • USB2.0 interface / powered • 36 channels • 4 GHz timing / 200 MHz state analysis 16M/4 8M/9 • 4-conditions (4 levels each) trigger 4M/18 2M/36, 4M/18, • Data Logger (HD storage) 6M/12, 8M/9, 12M/6, 18M/4, • Input Sensitivity 0.25Vpp 36M/2, 72M/1 • Qualified Storage 123 x 76 x 21 mm³ • Transitional Storage (8 channel mode can be used to store data for 4 hours) • Stackable with Acute or other brand DSO to form an MSO • Bus Trigger I : CAN, I²C, I²S, LPC, SMBus, SPI, SVI2, SVID, UART, USB1.1, ... , Time-out Bus Trigger I CAN, I²C, I²S, LPC, SMBus, SPI, SVI2, SVID, UART, USB1.1, ... • Bus Trigger II : eMMC 4.5, eSPI, MIPI SPMI, NAND Flash, SD 3.0, Serial Flash (SPI NAND), ... Bus Trigger II eMMC 4.5, eSPI, MIPI SPMI, NAND Flash, SD 3.0, Serial Flash (SPI NAND), ...(TL2236B+ Only) • Bus Decode I : BiSS-C, CAN, eMMC5.0, I²C, I²S, Nand Flash, ProfiBus, SD, SPI, SVID, UART, USB1.1, ... (70+ decodes) • Bus Decode II : MIPI DSI-HS, ... (Signal source: Other brand DSO or LA, not TravelLogic) Model Memory Bus Trigger Bus Decode TL2136B 18 Mb I I TL2236B 72 Mb I I TL2236B+ 72 Mb I, II I, II Software Window System Requirements • USB 2.0 port • XP, Vista, Win 7, Win 8 (32 / 64 bits) 1-Wire, 3-Wire, 7-Segment, A/D Mux Flash, AccMeter, ADC, APML, BiSS-C, CAN, Close Caption, CEC, DALI, DMX512, DP AUX, EDID, eSPI, eMMC 5.1/MMC, FlexRay, HDLC, Line Decoding, Line Encoding, HD Audio, HDQ, HID over I²C, I²C, I²C EEPROM, I²S, I80, IDE, ITU656, IrDA, JTAG, LCD1602, LIN, Lissajous, LPC, LPT, M-Bus, Math, MDIO, MHL CBUS, Microwire, MII, MIPI RFFE, Bus Decode I MIPI DSI, MIPI SPMI, Modbus, Nand Flash, NEC IR, PECI, PMBus, ProfiBus, PS/2, PWM, QI, RGB Interface, RC-5, RC-6, SD 3.0/SDIO 3.0, Serial Flash, Serial IRQ, SGPIO, Smart Card, SMBus, SMI, S/PDIF, SPI, SPI NAND, SSI, ST7669, SWD, SWP, SVI2, SVID, UART, UNI/O, USB 1.1, Wiegand, ..
    [Show full text]
  • Flex-Ray Is Designed for Plastic Injection Molding Machines
    International Journal of Science and Research (IJSR) ISSN (Online): 2319‐7064 Flex-Ray is Designed for Plastic Injection Molding Machines B. Gomatheeshwari1, M. S. Vishnu Priya2 1Student, Sri Muthukumaran Institute of Technology, Chennai – 600069, India 2Assistant Professor, Sri Muthukumaran Institute of Technology, Chennai – 600069, India Abstract: This innovative application of the Flex-ray technology with the ARM controller is implemented to monitor and control the process of the injection molding machine with the help of host computer. Embedded technology and Flex-ray field bus technology are utilized together for the efficient functioning of injection molding machine. The closed-loop control system, composed of the ARM controller and sensors, realizes the prompt adjustment of the processing parameters, such as temperature, flow, injection pressure and the control of multi-stage injection pressure in the molding process to produce best product in best quality. Flex-ray technology with Artificial Intelligence used in this process to monitor and control the parameters at the high transmission rate. Keywords: Flex-Ray Transceiver, injection moulding machine; distributed control system; artificial intelligence. 1. Introduction of the HSE communication role used in Foundation Fieldbus. At present, the control mode of injection molding machines is mainly stand-alone control, which cannot 2. System Architecture Design provide the network control function for injection molding machines. The maintenance and the management for the The ARM-based distributed intelligent control system machines are also limited to on-site management level. mainly consists of the host computer, FLEX-RAY This kind of operation and management mode is not only fieldbus, ARM controller as the slave computer and other unable to meet the requirements of automation and scale accessories, as shown in Fig.1.
    [Show full text]