courseware sample · 2011. 4. 7. · job sheet 3 complete nacelle operation counting completed...
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Electric Power / Controls
Courseware Sample
85303-F0
A
ELECTRIC POWER / CONTROLS
COURSEWARE SAMPLE
bythe Staff
ofLab-Volt Ltd.
Copyright © 2009 Lab-Volt Ltd.
All rights reserved. No part of this publication may be reproduced,in any form or by any means, without the prior written permissionof Lab-Volt Ltd.
Printed in CanadaJuly 2009
III
Table of ContentsIntroduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . V
Courseware Outline
PLC Applications – Wind Turbine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VII
Sample Job Sheet Extracted from PLC Applications – Wind Turbine
Exercise 1 Familiarization with the Wind Turbine . . . . . . . . . . . . . . . . . . . . . 3
Instructor Guide Sample Job Sheet Extracted from PLC Applications – WindTurbine
Exercise 1 Familiarization with the Wind Turbine . . . . . . . . . . . . . . . . . . . . 17
IV
V
Introduction
Programmable Logic Controllers (PLC's) represent state-of-the-art micropro-cessor-based electronics that make up technologically advanced control systemswith applications in virtually every segment of industry where automation is required.
This courseware sample is a representative extract of the manual (P/N 85303-20)that introduces students to PLC control of the Wind Turbine System, Model 8075-50.Throughout the manual, students learn how to program, connect, operate, andtroubleshoot a PLC acting as a control unit for a wind turbine nacelle.
The corresponding Lab-Volt Instructor Guide (P/N 85303-30) provides answers toall questions and activities found in the manual.
VI
PLC APPLICATIONS – WIND TURBINE
Courseware Outline
VII
Job Sheet 1 Familiarization with the Wind Turbine
Introducing the wind turbine system. Measuring the wind speedusing a counter and a timer in a structured ladder program. Scalingthe wind speed measurement. Comparing the wind speed withpreset values. Creating a manual control on the yaw-axis motor ofthe nacelle.
Job Sheet 2 Wind Tracking
Measuring wind direction and adjusting its scale. Implementingconditional tracking of the wind. Creating an automatic or a manualcontrol of position.
Job Sheet 3 Complete Nacelle Operation
Counting completed turns. Positional reset of the nacelle when therotation limit is reached. Automatic reset in case of wind shortage.
Job Sheet 4 Troubleshooting
Guided and non-guided ways of finding an inserted fault in the WindTurbine PLC.
Appendices A Lab-Volt PLC Trainers, Models 3240-2 and 3240-AB Ladder Program DesignC Boolean Algebra and Digital LogicD Troubleshooting ProceduresE Post-TestF Glossary of Terms
VIII
Sample Job Sheet
Extracted from
PLC Applications – Wind Turbine
1
FAMILIARIZATION WITH THE WIND TURBINE
PLC APPLICATIONS – WIND TURBINE 3
The energy needs of the world population are continuously increasing along with thedevelopment of new technologies and the industrialization of emergent countries.Electricity is one such indispensable resource needed in many aspects of modernlife. It is usually generated in power plants of the thermal type which uses one sortor another of fuel (coal, petroleum, fissionable elements…) to cause a heat-generating reaction driving turbines to produce electricity. Each method has itsdrawbacks such as environmental pollution, management of dangerous waste andlimited supply of fuel. Power plants using renewable resources are becoming muchmore prevalent as the focus is shifting towards environmentally-sound methods ofelectricity production. Energy produced by such plants comes from a naturalresource – such as water, sunlight, wind, tide – acting as a substitute to conventionalfuel in the power-generation process.
A wind turbine is a device designed to extract the energy stored in the wind in orderto convert it to electricity. The wind is naturally blowing at various speeds and fromdifferent directions as time passes. Once a location with a good wind potential hasbeen found, a wind turbine or an array of them can be installed to harness thatenergy. The wind will propel the aerodynamically-designed blades of the rotor up tosome angular speed thus driving a power generator inside the nacelle of the windturbine to produce electricity.
FAMILIARIZATION WITH THE WIND TURBINE
4 PLC APPLICATIONS – WIND TURBINE
Figure 1-1. A Wind Turbine.
FAMILIARIZATION WITH THE WIND TURBINE
PLC APPLICATIONS – WIND TURBINE 5
The nacelle is the nerve center of the wind turbine. It typically includes all themechanical devices (shafts, gearbox…) necessary to transmit mechanical powerfrom the hub of the rotor to the generator. It also contains a braking system to slowor stop the rotor, a system to control the orientation of the nacelle on its yaw axis,and a control unit automating the operating procedures according to the windconditions or the maintenance needs. Other essential parts of the nacelle are themeteorological instruments required to monitor the speed of the wind (anemometer)and its direction (wind vane).
Figure 1-2. Schematic of a Nacelle.
Lab-Volt's Wind Turbine System
The Wind Turbine System from Lab-Volt is made of two modules:
• Wind Generator, Model 3213• Nacelle Simulator, Model 3297
Figure 1-3 shows the Wind Generator from Lab-Volt. It is a device used to producea constant wind whose strength, as measured by the anemometer, can be variedsimply by moving the generator towards or away from the measuring instruments ofthe nacelle.
FAMILIARIZATION WITH THE WIND TURBINE
6 PLC APPLICATIONS – WIND TURBINE
Figure 1-3. Wind Generator, Model 3213.
1. Wind Outlet2. ON/OFF Switch3. 24 V DC Power Input
Lab-Volt's Nacelle Simulator is shown in Figure 1-4. It is designed to reproduce thekey characteristics of a wind turbine nacelle and to demonstrate the possibilities ofcontrol and automation programming.
FAMILIARIZATION WITH THE WIND TURBINE
PLC APPLICATIONS – WIND TURBINE 7
Figure 1-4. Nacelle Simulator, Model 3297.
1. Wind Direction Selector2. Nacelle3. Wind Vane4. Anemometer5. Turn Counter6. Turn-Limit Detector7. 24 V DC Power Input8. Motor Controls – Clockwise and
Counter-Clockwise Rotation
9. Wind Direction Analog Output(0 - 10 V DC)
10. Wind Speed Output (Pulse)11. Turn-Counter Output Contacts
(NO / NC)12. Turn-Limit Output Contacts
(NO / NC)13. Fault Panel (On the back panel)
Automated Control of a Wind Turbine
The control unit inside a nacelle is effected in the simulation by a PLC modulemonitoring the outputs of the instruments to control and optimize the operation of thewind turbine.
FAMILIARIZATION WITH THE WIND TURBINE
8 PLC APPLICATIONS – WIND TURBINE
The available outputs of the nacelle module are:
– The speed and direction of the wind. – A turn counter coupled to a limit detector.
The PLC has control over the yaw motor of the nacelle to track the wind or moveaway from it as the situation dictates. The different programs necessary to implementthe control routines proposed in the following job sheets will have to be programmedon the PLC with the help of a computer running a ladder programming software.
Operation of the Wind Speed Output
The anemometer is the device measuring the speed of the wind as it blows on thewind turbine. The Wind Speed output is a frequency output, a pulse being generatedevery time the anemometer completes a revolution.
Figure 1-5. Time Diagram of the Wind Speed Output.
In the following job sheets it will be required to evaluate the wind speed. This is ofprime importance given that a typical wind turbine starts operating at a wind speedabove 4 m/s (about 15 km/h – 9 mph) and has to cut-off to avoid damaging itscomponents when the speed gets higher than 17 m/s (about 60 km/h – 37 mph). Using a timer allows for the calculation of the wind speed when a dividing componentis added to the ladder logic. A counter can be added to the design if the wind speedis to be averaged over the course of a few revolutions.
Divide Instruction
The Divide (DIV) instruction is a standard mathematical operation used to divide anumber (Source A) by another (Source B). The result is stored in a data file(Destination), typically in the Float data file (F8). As an example, say we know thedistance travelled by the anemometer to be some value X and the time it took to doso to be stored in the accumulator of a timer. The average speed can be calculatedand saved in the F8 data file by using a rung similar to the one displayed inFigure 1-6.
FAMILIARIZATION WITH THE WIND TURBINE
PLC APPLICATIONS – WIND TURBINE 9
Figure 1-6. A Typical Use of the DIV Instruction.
Precise scaling of the anemometer is not required for the following job sheets. Avalue for X (see previous paragraph) must be determined such that the calculatedwind speed in the strongest wind condition attainable – i.e. when the wind generatoris closest to the nacelle – is about 65 km/h (40 mph).
10 PLC APPLICATIONS – WIND TURBINE
1
FAMILIARIZATION WITH THE WIND TURBINE
PLC APPLICATIONS – WIND TURBINE 11
OBJECTIVES
• Become familiar with some components of the Nacelle module.• Create and implement a ladder program using a timer to measure the wind
speed.
PROCEDURE
G 1. The first step in using the wind turbine application is to establish therequirements of the control routine. The program to be written for this JobSheet must allow you to perform the following tasks:
• A toggle switch is used to manually command a rotation of the nacellein the clockwise direction. Another one is used to perform a rotation inthe counter-clockwise direction. The nacelle stands still if both switchesare simultaneously activated.
• The wind speed is calculated using a timer and a divider. A pilot light isenergized whenever the wind becomes too weak to drive the windturbine (15 km/h – 9 mph) and another one lights up if it becomes toostrong (60 km/h – 37 mph).
The ladder program uses only the following RSLogix instructions:
XIC - XIO - OTE - TON - DIV - GEQ - LEQ - NEQ
G 2. Use these I/O connections:
FAMILIARIZATION WITH THE WIND TURBINE
12 PLC APPLICATIONS – WIND TURBINE
Figure 1-7. Interface Connections for the PLC Implementation.
FAMILIARIZATION WITH THE WIND TURBINE
PLC APPLICATIONS – WIND TURBINE 13
PLC ADDRESS PLCTERMINALS CONNECTED TO / USED AS
I:0/0 Input 0 Wind Speed Output of theNacelle
I:0/3 Input 3 Toggle Switch 4 / Used forManual Clockwise Control
I:0/4 Input 4 Toggle Switch 5 / Used forManual Counter-ClockwiseControl
O:0/0 Output 0 Motor Control of the Nacelle -Clockwise Input
O:0/1 Output 1 Motor Control of the Nacelle -Counter-Clockwise Input
O:0/4 Output 4 - / Pilot Light - IndicatesDangerous Wind Speeds
O:0/5 Output 5 - / Pilot Light - Indicates a WeakWind
Table 1-1. PLC I/0 Connections of Job Sheet 1.
G 3. The manual controls of the motor must be designed in such a way as toavoid sending a contradictory signal to the motor in the nacelle, i.e. acommand to turn both in the clockwise and in the counter-clockwisedirections at the same time.
What are the boolean equations preventing such a contradictory command?These equations relate outputs O:0/0 and O:0/1 to inputs I:0/3 and I:0/4.Refer to Appendix B and C if necessary.
A well-designed system will override illogical commands to always producecoherent results. Always strive for such designs!
G 4. Think of an efficient ladder design to calculate the speed of the wind. Youshould be able to write a program with as few as two rungs using only XIC,XIO, NEQ, DIV, and TON instructions. The NEQ (Not Equal) instruction isnecessary to avoid division by zero. Such an undefined operation results ina computational error and must be avoided. The speed value should bestored in a file as a Float by choosing destination F8:0. Sketch this ladderprogram in the space provided.
FAMILIARIZATION WITH THE WIND TURBINE
14 PLC APPLICATIONS – WIND TURBINE
G 5. Two pilot lights are used to indicate if specific wind conditions are met ornot. Using comparator logic, translate those conditions into a short ladderprogram which you can draw in the space provided.
Reminder:
O:0/4 is lit if the wind speed is greater or equal to 60 km/h (37 mph).O:0/5 is lit if the wind speed is lower or equal to 15 km/h (9 mph).
Can you think of another indicator which might be useful in the context of awind turbine operation? How would you proceed to implement it?
G 6. Start RSLogix 500 and compile all the results obtained so far in a singleladder program.
G 7. Test and comment your ladder.
G 8. Demonstrate the operation of your program to your instructor.
G 9. Print your ladder program.
G 10. Close RSLogix 500 and turn off the PLC.
Disconnect and store all leads and components.
Name: Date:
Instructor's approval:
Instructor Guide
Job Sheet Extracted from
PLC Applications
Wind Turbine
PLC Applications – Wind Turbine
PLC APPLICATIONS – WIND TURBINE 17
JOB SHEET 1 FAMILIARIZATION WITH THE WIND TURBINE
ANSWERS TO PROCEDURE STEP QUESTIONS
G 3.
G 4.
Figure 1-1. Measurement of the Wind Speed.
PLC Applications – Wind Turbine
18 PLC APPLICATIONS – WIND TURBINE
G 5.
Figure 1-2. Comparator Logic.
There are many other indicators which can be of interest. Among them are:
– A pilot light indicating an unsteady wind (wind speeds must then becompared over time).
– A pilot light indicating the wind is in the normal operating range.– A pilot light indicating a command is contradictory (such as asking for
clockwise and counter-clockwise rotations at the same time). – Etc...
PLC Applications – Wind Turbine
PLC APPLICATIONS – WIND TURBINE 19
G 6.
Figure 1-3. Ladder Program of Job Sheet 1.
PLC Applications – Wind Turbine
20 PLC APPLICATIONS – WIND TURBINE
Figure 1-4. Ladder Program of Job Sheet 1 (cont'd).
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