1 / 67

CRANES

TURBINE. CRANES. NEA39. PLANT STATUS!. General System Diagram of. Palo Verde Nuclear Generating Station. Legend::. Safety Injection Systems. Reactor Coolant System. To Switchyard. Containment Building. Main Steam System. Main Feedwater System. Main Condensate System.

italia
Download Presentation

CRANES

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. TURBINE CRANES NEA39 Turbine Crane

  2. PLANT STATUS! General System Diagram of Palo Verde Nuclear Generating Station Legend:: Safety Injection Systems Reactor Coolant System To Switchyard Containment Building Main Steam System Main Feedwater System Main Condensate System CONTAINMENT SPRAY Circulating Water System Transformer Turbine Building Auxiliary Feedwater System Cooling Tower and Fans Safety Injection Tank Moisture Separator Reheaters MSSVs ADVs 8 8 8 Steam Generator Auxiliary Building MSIV Pressurizer MTSV Control Rods MSSS Shutdown Heat Exchanger HP LP LP LP Generator Bldg. Turbine Turbine Turbine Turbine Equipment Cooling MTCV Z From Auxiliary Feedwater Pumps Containment Spray Pump Turbine Bypass Valves Reactor Core Refueling Water Tank Condensate Pump Reactor Coolant Pump Main Condenser Low Pressure Safety Injection Pump (HP) Feedwater Heaters (LP) Feedwater Heaters Circulating Water Pump High Pressure Safety Injection Pump Feedwater Regulation Valve Main Feedwater Pump Polishing Demineralizers Containment Sump Turbine Crane PV Daily Status Report

  3. Turbine Crane

  4. Walk downs • Review instructions to ensure workable and adequate • Right Parts/materials/tools • Permits • Relevant Operating Experience Turbine Crane

  5. Pre Job Briefs • Understand the Task • Critical Steps identified and OE used AND what actions are being taken in reference to these two areas • Two Minute Drills: • Hazards identified AND what are actions are you taking Turbine Crane

  6. Procedure Use & Adherence • WO / procedure in hand & latest revision • Place keepers being used • Sign steps as you go • Follow & understand steps - STOP if can't or don't Turbine Crane

  7. TURBINE CRANE • Terminal Objective Given references provided by the Instructor, the Plant Electrician will maintain Turbine Building Cranes as demonstrated by achieving a minimum of 80% on a written examination. Turbine Crane

  8. . Multi Stud Tensioner

  9. PRE-JOB BRIEF • Identify Critical Steps • Identify Error Precursors • Worst thing that can happen • Error prevention defenses to be used • Actions to assure proper configuration control Turbine Crane

  10. TURBINE CRANE EO 1.6 Describe the Programming of the Allen Bradley SLC 5/04 Programmable Logic Controller

  11. Software RSLogix 500 • RSLogix software is a Windows ladder logic programming tool for SLC500 processors. This software allows the user to: • Establish Communications with SLC 500 processors. • Display and monitor process data including FAULT Codes • Create and Modify new ladder logic • Configure your I/O modules Turbine Crane

  12. Off-line Computer Operation ***Projects that reside on the hard disc of a computer*** Viewing Projects: • Projects are files that store all of the program logic and data for a single processor. • Example: Turbinecrane.rss Turbine Crane

  13. Turbine Crane

  14. Turbine.RSS Turbine Crane

  15. Off-line Computer Operation Project Files: DataBase Files • Files that contain information which is not used by the processor and is typically stored in the computer memory only. • Examples: Custom Data Monitors, Trends etc… Turbine Crane

  16. Turbine.RSS Turbine Crane

  17. Off-line Computer Operation Processor Files: • Files that can be modified or monitored from the computer while they are being used by the PLC processor • Examples: Data Files, Program Files, Force Files. Turbine Crane

  18. Turbine.RSS Turbine Crane

  19. Off-line Computer Operation Viewing Ladder Logic: • To view ladder logic, you must first open the project you are interested in. • Next, you are to open the ladder file you are interested in i.e. LAD02 Turbine Crane

  20. Turbine Crane

  21. On-line Computer Operation ***Using the computer to view or work with a project that is loaded in a SLC 500 processor.*** Online: • The computer must be in continuous communication with the processor to allow the following actions can be performed: • Monitor or modify a project loaded in a processor • Monitor data while it is being collected • Modify data stored in a processor Turbine Crane

  22. Turbine Crane

  23. On-line Computer Operation ***Using the computer to view or work with a project that is loaded in a SLC 500 processor.*** Download: • Transfers a copy of a project from a computer to a processor. *****CAUTION***** Downloading will overwrite the program that is currently installed on the PLC. Turbine Crane

  24. On-line Computer Operation ***Using the computer to view or work with a project that is loaded in a SLC 500 processor.*** Upload: • Transfers a copy of a project from a PLC Processor to the memory of a computer. • Because uploading allows the user to view the actual project that is on the processor, it is commonly used by maintenance personnel to troubleshoot and monitor a project. Turbine Crane

  25. Turbine Crane

  26. Connecting a Computer and Going On-line • RSLinx software must be loaded and enabled to allow communication between the computer and the processor. • A Communications Driver must be established to allow the software to communicate with the processor. • We will use Data Highway + (DH+) or RS-232 connection typically. • A cable will run from the computer to the Processor to establish the link. • Typically this will either be a RS-232 link or a PCMK (DH+) connection. • A USB to DH+ is also currently available. Turbine Crane

  27. Modes of Operation There are 3 modes of control for the SLC500 processor and they allow different functions to occur. They are selected from a keyswitch on the front of the processor and allow functions to occur as follows: Turbine Crane

  28. Processor Modes RUN – This is the mode you should find the PLC processor in. It allows the processor to perform its intended function and control the crane. • No programming can be performed in this mode. Turbine Crane

  29. Processor Modes PROGRAM – (PROG) When this mode is selected, the operation of the crane will cease. Downloading / Uploading and modification of processor projects can occur. Turbine Crane

  30. Processor Modes REMOTE – (REM) This mode is used to control a processor’s operating mode from the laptop connected to the processor. There are 3 separate modes of remote operation and they must be selected by the computer you have connected. Turbine Crane

  31. Processor Modes REMOTE • Remote RUN – This will allow for crane operation while the computer is connected. • Remote PROGRAM – This is the same as the regular program mode. • Remote TEST – This mode will allow you to run a program from a computer but it will disable the outputs of the PLC. Turbine Crane

  32. Turbine Crane

  33. Memory Layout and System Addresses SLC 500 Software Address Characteristics: Example Address: • B 15 : 3 / 2 • B – indicates the File Type (B- Binary Bit) • 15 – indicates the File Number • 3 – indicates the Element number • 2 – indicates the Bit number Turbine Crane

  34. Memory Layout and System Addresses SLC 500 Software Address Characteristics: Example Address: • T 14 : 2. PRE • T – indicates the File Type (T – Timer) • 14 – indicates the File Number • 2 – indicates the Element Number • PRE – would indicate a word address Turbine Crane

  35. Turbine Crane

  36. I : 3 / 10 • I –indicates the Module Type (I- Input) • 3 –indicates the Slot Number • 10–indicates the Terminal Number Memory Layout and System Addresses SLC 500 Hardware Address Characteristics: **Address for a hardware device (input or output) is directly determine by the module slot number and terminal to which the hardware device is wired. Example Address: • I : 3 / 10 • I – indicates the Module Type (I- Input) • 3 – indicates the Slot Number • 10– indicates the Terminal Number Turbine Crane

  37. Turbine Crane

  38. I : 3 / 10 • I –indicates the Module Type (I- Input) • 3 –indicates the Slot Number • 10–indicates the Terminal Number Memory Layout and System Addresses SLC 500 Hardware Address Characteristics: Example Address: • O : 5 / 3 • O – indicates the Module Type (O – Output) • 5 – indicates the Slot Number • 3 – indicates the Terminal Number Turbine Crane

  39. Turbine Crane

  40. F I N D THE H A R D W A R E A D D R E S S C O U N T E R M O D U L E # 4 Turbine Crane

  41. Turbine Crane

  42. I : 3 / 10 • I –indicates the Module Type (I- Input) • 3 –indicates the Slot Number • 10–indicates the Terminal Number Memory Layout and System Addresses SLC 500 Hardware Address Characteristics: Analog Example Address: O : 4 . 2 • O – Analog Module Type (O – Output) • 4 – indicates the slot number • . – indicates the Word Delimiter • 2 – indicates the analog channel number Turbine Crane

  43. Turbine Crane

  44. Turbine Crane

  45. Hardware to Data Table Relationships Discrete modules • Each I/O module terminal point is represented by a bit in the input or output data tables. • Radix determines the data display available for each digit of a number in a numbering system (i.e. Binary is base 10 and uses a 0 or a 1) Turbine Crane

  46. Turbine Crane

  47. Turbine Crane

  48. Hardware to Data Table Relationships Analog modules • Will be represented by a Decimal equivalent. • Radix must be changed to Decimal to view the number Turbine Crane

  49. Turbine Crane

More Related