GE DEH-211 manual Getting Started, First Steps, Understanding Terminology

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Getting Started

First Steps

If you are already familiar with PMCS, simply review the system requirements and skip ahead to Chapter 3.

Getting started with PMCS is easy. This chapter explains power management and leads you through the steps to take prior to installing your PMCS software. If you need help with your PMCS system, the GE Technical Support telephone number is given at the end of this chapter.

Understanding Terminology

Power-management system terminology can be intimidating to new PMCS users. The list below defines many of the important terms and acronyms used in this guide and other PMCS manuals. Refer back to this list as new terms are presented later.

Baud rate: A measurement of a communication channel's signaling rate or information-carrying capacity. Communicating devices typically have configurable baud rates to provide compatibility with various speed communication networks. Higher baud rates generally provide faster data-refresh times.

CIMPLICITY HMI: An industry-standard SCADA software package providing flexible, accurate, and easy-to-use graphics. CIMPLICITY HMI is based on a client- server architecture, consisting of Servers and Viewer Workstations. Servers are responsible for the collection and distribution of data. Viewer Workstations connect into Servers and have full access to the collected data for viewing and control actions. Servers and Viewer Workstations can be easily networked together to seamlessly share data without the need to replicate your point database from node to node.

CIMPLICITY HMI Server Development: CIMPLICITY HMI Server Development allows you to create new projects and can also function as a runtime system.

CIMPLICITY HMI Server Runtime: CIMPLICITY HMI Server Runtime systems do not support project configuration. They may be used as runtime systems only.

CIMPLICITY HMI Viewer Runtime: CIMPLICITY HMI Viewer Runtime connects to Servers for viewing data and controlling actions.

Commnet: A GE Industrial Systems standard for device communications that specifies the communication protocol and the communication network.

Communication network: A physical standard for wiring and interconnection of communicating devices. A communication network standard usually includes specifications of voltages, maximum cable-run lengths, shielding, termination, and

8 Getting Started

CIMPLICITY PMCS Read-This-Book-First

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Contents Power Leader TM Enhanced MicroVersaTrip-C SR489 Generator Management Relay Back to Main Contents Configuring the Software Introduction How to Use this BookWelcome About Cimplicity Pmcs Version FeaturesPerformance Cimplicity Pmcs Read-This-Book-First Introduction Supported Devices Device Firmware Revision SupportedPage First Steps Getting StartedUnderstanding Terminology Cimplicity Pmcs Read-This-Book-First Getting Started Getting Started Cimplicity Pmcs Read-This-Book-First Where to Get Help System RequirementsWhat’s next? This page left blank intentionally Installing Cimplicity Installing the SoftwareComputer Preparation Installing Additional Software RS485 Pmcs Network InterfacesEthernet Pmcs Network Interfaces Local Area Network LAN Interfaces Installing the EPM Software Components Installing the Pmcs software ELicensing Pmcs softwareDay Trial Licensing via the WebViewer Workstation Installation Host PC InstallationLicense by Phone Pmcs Installation Steps Cimplicity Pmcs Read-This-Book-First Installing the Software Installing the Software Cimplicity Pmcs Read-This-Book-First At the Choose Destination Default is C. Click Next Installing the Software Cimplicity Pmcs Read-This-Book-First Cimplicity Pmcs Read-This-Book-First Installing the Software Installing the Software Cimplicity Pmcs Read-This-Book-First Cimplicity Pmcs Read-This-Book-First Installing the Software Installing the Software Cimplicity Pmcs Read-This-Book-First Cimplicity Pmcs Read-This-Book-First Installing the Software Installing the Software Cimplicity Pmcs Read-This-Book-First Cimplicity Pmcs Read-This-Book-First Installing the Software Installing the Software Cimplicity Pmcs Read-This-Book-First Cimplicity Pmcs Read-This-Book-First Installing the Software Installing the Software Cimplicity Pmcs Read-This-Book-First PQ Analyst Installation Steps Installing the Software Cimplicity Pmcs Read-This-Book-First Cimplicity Pmcs Read-This-Book-First Installing the Software Un-elicensing Pmcs Uninstalling Pmcs Uninstalling the Pegasys System Log ServiceInstalling the Software Cimplicity Pmcs Read-This-Book-First Reinstallation Steps Upgrading from previous versions to Pmcs Organize Your Information Configuring the SoftwareHost PC View Node COMHost PC Configuration Configuration ProcedureViewer Workstation Configuration EPM Software Components Configuration EPM Device Special Considerations IntroductionION Designer Programming Devices and Software Nodes Network Builder Building the Network Configuration FileEPM Software Components Communications Server System CommunicationsWorkstation Configuration Guidelines Configuring the EPM Device Network Running Network BuilderBuilding the Power-Monitoring Network in NetBuilder Adding a WorkstationAdding Software Nodes Adding an Ethernet Site Page Adding Devices Meters Saving and ExitingThis page left blank intentionally Using MMS Servers with Pmcs What is an MMS Server?Installation for Windows NT Preparing the MMS Server for use with Pmcs Page Page Page This page left blank intentionally Index GE Industrial Systems

DEH-211 specifications

The GE DEH-211 is a cutting-edge digital electro-hydraulic (DEH) control system developed by General Electric to enhance the performance and efficiency of hydroelectric and steam turbine operations. Notably recognized for its reliability and advanced features, the DEH-211 integrates modern technologies to facilitate precise control of turbine operations.

One of the main features of the DEH-211 is its robust digital architecture, which allows for real-time data processing and system monitoring. This digital platform enhances the overall performance by providing faster response times and improved signal processing, which are crucial for maintaining optimal turbine performance under varying operational conditions.

The DEH-211 employs advanced control algorithms that enable superior speed governing and load control. This results in increased stability and reliability for turbine operation, helping to achieve optimal efficiency levels. The DEH-211 also integrates advanced feedback mechanisms, ensuring that the system can quickly adapt to changes in load and other operational variables.

Another noteworthy technology integrated into the DEH-211 is its digital communication capabilities. The system supports various communication protocols that facilitate seamless integration with existing plant control systems and other digital devices. This flexibility allows operators to achieve a higher level of automation and centralize control processes, ultimately leading to reduced operational costs.

The DEH-211 is designed with redundancy in mind, which is crucial for applications where system availability is paramount. The system features dual processors and dual communication paths, ensuring that there is a backup in place should any component fail. This redundancy not only enhances reliability but also instills confidence among operators regarding safe plant operations.

Additionally, the DEH-211 has been engineered for ease of use. Its user-friendly interface allows operators to monitor and manage turbine operations efficiently. Features such as graphical displays and intuitive controls enhance accessibility, enabling operators to make informed decisions quickly.

In summary, the GE DEH-211 stands out in the realm of turbine control systems due to its advanced digital technology, precise control capabilities, and emphasis on redundancy and reliability. With its ability to integrate seamlessly with existing plant infrastructure and promote enhanced efficiency, the DEH-211 is a formidable asset for modern power generation facilities seeking to maximize their operational potential. This system not only meets the demands of today's energy landscape but also positions itself for future advancements in turbine control technology.