GE X3.28 manual Table of Contents

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Protocol X DCA
Configuration Guide	GE Energy Services

About this Guide
About this Guide		vii
Who should use this Guide		vii
Additional Documentation		viii
Overview
Product Perspective		ix
Chapter 1: Configuring Tables
1.1	ANSI X3.28 DCA Configuration Tables	1
1.2	Configuration Sequence	2

Chapter 2: Configuring the Main Application Table (A197MAIN)

Chapter 3: Configuring the Communication Port Table (A197_COM)

Chapter 4: Configuring the SRU Table (A197_SRU)

Chapter 5: Configuring the Partition Definition Table (A197_PAR)

Chapter 6: Configuring System Parameters Table (A197_SYS)

Chapter 7: Configuring the Virtual Connection Table (A197_VC)

Restricted	A197-0CG-1.00-2
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Contents Allen-Bradley Ansi X3.28 DCA Configuration GuideTrademark Notices Table of Contents Appendix a Messages Logged by the Ansi X3.28 DCA Configuring WIN for the Ansi X3.28 DCASystem Overview List of FiguresList of Tables About this Guide About this GuideWho should use this Guide Additional Documentation Product Perspective OverviewSystem Overview Table Name Description Configuring TablesAnsi X3.28 DCA Configuration Tables Ansi X3.28 DCA Configuration TablesConfiguration Sequence Configuring the Main Application Table A197MAIN Main Application Configuration Table ParametersName Range Description Protocol X DCA Communication Port Configuration Table Parameters Configuring Communication Port Table A197COMProtocol X DCA Baud Rate One Character Time ms Character TimesProtocol X DCA SRU Configuration Table Parameters Configuring the SRU Table A197SRUProtocol X DCA Partition Definition Table Parameters Configuring the Partition Definition Table A197PARWord Address System Parameter Unit Type Start Address word address Num. WordsSystem Parameters Table Parameters Configuring System Parameters Table A197SYSCoupler for Allen-Bradley Data Highway System Parameters Address System Parameter Unit Value DefaultConfiguring the Virtual Connection Table A197VC Field Range Description Virtual Connection Configuration Table ParametersWesdac Point Allocation Configuring WIN for the Ansi X3.28 DCAProtocol X DCA A197 Appendix a Messages Logged by the Ansi X3.28 DCAF002 A197SRU rec x, duplicate SRU address y Fatal Error MessagesF004 COM rec x, Interchar Timeout must be less than Rx Time F001 Unable to locate table tablenameF101 Unable to find table tablename F005 A197PAR rec x and y, Partitions overlapF006 A197COM rec x, Only one SRU allowed in Full-Duplex F100 Future expansion points not NullptrF105 Not enough memory F102 Unable to open a channel to WINF103 Unable to create an exchange, name, status=y F104 Unable to spawn process, processnameF109 User data memory overflow F107 Unable to get pointer table nameF108 Not enoughx points, y required Wesdac Point TypesF203 L062COMEXTENSIONS should be initialized F200 Unable to get pointer to COM config record =F201 Unable to create exchange, exchage, status=x F202 Unable to spawn processE110 Unable to open comport, status = Non-Fatal Error MessagesE101 Restart failed for processname E102 Not enough memoryE112 comport unable to set timers, status = E111 comport unable to set parameters, status =E201 Com initialization failed, status = comport E205 Encountered error = x while closing comport E202 Not enough memoryE204 a child process has died, suspending I101 Unable to find table A197MAIN, deleting Information MessagesControl Request Return Codes

X3.28 specifications

The GE X3.28 is a sophisticated commercial jet engine developed by General Electric, known for its innovative technologies and remarkable performance. Designed specifically for the next generation of regional jets, the X3.28 showcases an impressive blend of efficiency, reliability, and low emissions, setting a new benchmark in the aviation industry.

One of the standout features of the X3.28 is its advanced turbofan design, which combines a large bypass ratio with cutting-edge materials to enhance performance while reducing fuel consumption. The engine is built with lightweight composite materials that not only improve fuel efficiency but also contribute to overall weight reduction in regional aircraft. This is crucial for smaller jets that rely on maximizing payload while minimizing operational costs.

The X3.28 is equipped with an innovative high-pressure compressor system that utilizes advanced aerodynamics to ensure optimal airflow and pressure ratios. This technology enhances the engine's thrust performance, allowing aircraft to take off and climb efficiently even from shorter runways. Additionally, the fan blades are designed using state-of-the-art computational fluid dynamics simulations, which help in achieving higher performance and operational reliability.

Another significant characteristic of the X3.28 is its noise reduction capabilities. By employing advanced sound-attenuating technologies in the fan and exhaust systems, the engine meets stringent noise regulations, making it suitable for operations in urban areas and near sensitive environments. This focus on environmental considerations extends to its low emissions profile, making it a more eco-friendly choice compared to older engine models.

The engine also incorporates digital monitoring and control systems that provide real-time data on performance metrics, enabling more efficient maintenance scheduling and enhanced operational safety. This predictive maintenance approach helps airlines reduce downtime and streamline their operations, ultimately contributing to cost savings.

In summary, the GE X3.28 stands out in the competitive market of regional jet engines due to its advanced technologies, exceptional efficiency, and commitment to sustainability. With its focus on performance and environmental responsibility, the X3.28 is poised to lead the way in the future of regional aviation, making it an attractive option for airlines looking to modernize their fleets while maintaining operational excellence.