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Users Guide For Simple Cycle
EfficiencyMapTM Performance Monitoring System
Version 5.0
Enter Software, Inc.
Menlo Park & Davis, CA
Houston, TX
Graz, Austria
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NOTICE
ENTER SOFTWARE, INC. MAKES NO WARRANTIES OR
REPRESENTATIONS, EITHER EXPRESSED OR IMPLIED, ON
ANYTHING IN THIS MANUAL OR THE ACCOMPANYING
SOFTWARE. NO REPRESENTATIONS OR WARRANTIES ARE
MADE OF MERCHANTABILITY OR FITNESS FOR ANY
PARTICULAR PURPOSE.
ENTER SOFTWARE, INC. SHALL NOT BE HELD LIABLE FOR
ANY LOSS OF USE, INCIDENTAL, OR CONSEQUENTIAL
DAMAGES WHATSOEVER ARISING OUT OF THE USE OF
THIS SOFTWARE MANUAL, EVEN IF ENTER SOFTWARE,
INC. HAS BEEN ADVISED, KNEW OF, OR SHOULD HAVE
KNOWN OF THE POSSIBILITY OF SUCH DAMAGES.
Copyright 1989-1997
Enter Software, Inc.
All Rights Reserved
EfficiencyMapTM, GateCycleTM, and the OptimizerTM are trademarks of Enter Software, Inc.
PI System is a trademark of OSI Software, Inc. Windows NTTM and WindowsTM are
trademarks of Microsoft Corporation.
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Introduction
This users guide provides an overview of the EfficiencyMapTM SimpleCycle Performance Monitoring Software. It is intended to familiarize the
reader with the various EfficiencyMap software features, serve as a
reference to key system features, and provide examples on how
EfficiencyMap is used for performance analysis. It is assumed that the
reader has a working knowledge of Microsoft Windows NTTM. If any
problems, questions or comments concerning the software, documentation,
etc., arise, please contact Enter Software, Inc.
Enter Software, Inc.
1490 Drew Avenue, Suite 180
Davis, CA 95616
Phone 530/757-1240
Fax 530/757-1571
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TABLE OF CONTENTS
1. Introduction and Quick Start to EfficiencyMap and EmapView Version 5.0 .... 3
1.1 Heat Balance Data Validation.................................................................... 4
1.2 Performance Calculations.......................................................................... 5
2. EfficiencyMap Calculation Cycle..................................................................... 7
2.1 Cross Reference Data Processing .............................................................. 7
2.2 Performance Calculations........................................................................ 11
2.2.1 Calculated Performance ................................................................. 11
2.2.2 Expected Calculations.................................................................... 11
2.2.3 Corrected to Reference Calculations .............................................. 12
2.2.4 Reference Data................................................................................. 12
2.2.5 Performance Example....................................................................... 12
3. EmapView.................................................................................................... 15
3.1 Emap View............................................................................................. 15
3.2 EmapView Performance Report and Sensor Report Forms...................... 17
3.2.1 Performance Report ......................................................................... 17
3.2.2 Sensor Report .................................................................................. 18
3.2.3 Error Log......................................................................................... 19
3.3 EmapView Gas Turbine Data Form......................................................... 19
4. Application Examples ................................................................................... 24
4.1 Applying EfficiencyMap.......................................................................... 24
4.2 Validated Vs. Measured Fuel Flow.......................................................... 24
4.3 Validated Compressor and Expander Efficiencies .................................... 26
4.4 Tracking Compressor Efficiency Improvements from Online and
Off-line Washes ....................................................................................... 27
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5. Appendices ................................................................................................... 29
Appendix A. EfficiencyMap File Structure .................................................... 30
Appendix B. Variable Name Descriptions...................................................... 32
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1. In t roduct ion and Quick Star t to Simple
Cycle Eff ic iencyMap and EmapView
Version 5.0
Introduction
Efficiency Maintenance Analysis Program Version 5.0 (EfficiencyMap 5.0) is a data
validation and performance monitoring software package. EfficiencyMap performs a gas
turbine heat balance to obtain validated data , from which actual, expected , and corrected
performance parameters are calculated. The validated data and performance calculation
help operators and plant engineers to identify poorly measured data and the causes of
performance degradation. The motivation to account for performance and/or sensor
degradation is high because fuel costs alone can be $5,000 to $8,000 per hour for an 80
MW combustion turbine at full load.
The EfficiencyMap software system includes EmapView, a powerful Windows display
tool that allows the user to view the current set of plant data online and compare measured,
validated, expected, and corrected values. In addition to the other features, EmapView
also contains a Sensor Report and a Performance Report. The Sensor Report identifies the
gas turbine measured data points from the Distributed Control System (DCS) that deviate
the furthest from their validated values. The Performance Report sorts the gas turbine
performance parameters by the difference between their expected and calculated
performance. These reports are important tools that allow the operator to identify,
prioritize and correct gas turbine performance degradation.
Using EmapView
To start EmapView, go to the Enter Software Program Group in the Windows NT
Program Manager. In the Program Manager, there will be an icon entitled EmapView.
Double click on the icon to start the interface. When the interface window appears, there
will be three (3) pull-down menus entitled File, View, and Window. Pulling down
the View menu allows the user to select from the different data forms that provide access
to the current snapshot data within the EfficiencyMap Heat Balance and Performance
Calculation modules. The Window option allows the user to select among the open
Windows or view them in a cascade format. The File menu option allows the user to
print the displayed view and to exit from the EmapView program.
If your site has multiple gas turbines then there will be multiple EmapView icons (one
EmapView icon for each site gas turbine) located within the Enter Software Program
Group. Each EmapView icon is labeled (i.e. Gas Turbine 1, Gas Turbine 2, etc.) to
correspond to a specific turbine and will display performance data for that gas turbine.
EfficiencyMap Overview
EfficiencyMap is a model-based data validation, performance monitoring diagnostic
system. EfficiencyMap retrieves measured data from a plants Distributed Control System
(DCS) and performs a least-squares minimization (described below), producing a validated
set of heat balance data. This validated data satisfies a mass and energy balance of the gas
turbine, which the measured data is unlikely to do because of transducer error. This
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method of data validation throws out inaccurately measured data and provides a
representation of the gas turbine conditions which is more accurate than the raw, measured
data. Another important advantage is that the validated data provides values for important
gas turbine parameters which are not directly measured, such as gas turbine air flow and
turbine inlet temperature.
Performance calculations which use this validated data are more accurate and morereliable than those based directly on measured data from the gas turbine control system.
The performance calculations are based on gas turbine correction curves modified to
produce accurate and consistent results and/or Enter Software correlations in conjunction
with the validated data to calculate current, expected and corrected performance. All
results from the validated data and performance calculations are reported back to the user,
through the online EmapView interface. If you have any problems with your
EfficiencyMap installation please contact Enter Software Inc.
The following sections provide more detailed information on the EfficiencyMap heat
balance data validation approach and the EfficiencyMap performance calculations.
1.1 Heat Balance Data ValidationEfficiencyMap performs a heat balance data validation with the use of a least-squares, non-
linear minimization mathematical algorithm.
The form of the least-squares optimization is:
( )
Minimize
( )
where
Subject to
1) Mass and Energy Balances
2) Simple Constraints
=
=
measured value validated value
uncertainty
i
i i
i
uncertaintyi
percent uncertaintyi
reference measurement
2
1
[ ]
Each measured value obtained from the gas turbine control system is assigned a variable name
(measured value) that remains constant for each calculation cycle. Typical measurements for
a frame gas turbine are as follows:
Power
Fuel Flow
Fuel Temperature
Compressor Inlet Temperature
Compressor Discharge Temperature
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Compressor Discharge Pressure
Steam/Water Injection Flow
Steam/Water Injection Temperature
Steam/Water Injection Pressure
Inlet Pressure Drop
Outlet Pressure Drop
Exhaust Temperature
For this gas turbine measurement set there are enough equations and constraints to calculate
the gas turbine exhaust flow and validate the gas turbine fuel flow (or one other measurement
if there is high confidence in the gas turbine fuel flow measurement). The goal of the
optimization is to find the best set of validated values (exhaust and fuel flow) that deviates
from the measured values as little as possible while still satisfying the mass and energy
balances that model the gas turbine. Finding this set of validated values minimizes the aboveobjective function.
1.2 Performance Calculations
The accuracy of performance calculations is greatly improved by the use of the validated data.
Gas turbine correction curves provided by the vendor and/or Enter Software correlations are
used to compute expected and corrected values for important plant parameters. The
calculations also compare current performance to expected performance and corrected
performance to reference condition performance. These deviations are then reported to the
user.
EfficiencyMap executes the performance calculations using both measured and validated data
after running the least-squares heat balance data validation routine. The performance
parameters calculated by simple cycle EMAP include:
Power
Heat Rate (using validated fuel flow)
Exhaust Flow
Exhaust Temperature
Fuel Flow
Inlet Pressure Drop
Outlet Pressure Drop
Compressor Efficiency
Expander Efficiency
Turbine Inlet Temperature
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Expected, corrected, and deviation calculations are also performed on the performance
parameters (not including turbine inlet temperature). In total, there are six (6) primary
categories of performance calculations, as indicated in Table 1.2.1 (using heat rate as an
example).
Performance Calculation
Name:
Description:
Measured Heat Rate Heat rate calculated from measured gross power and
measured fuel flow
Validated Heat Rate Heat rate calculated from validated gross power and
validated fuel flow
Expected Heat Rate Expected heat rate calculated from current and reference
conditions using engine performance curves
Corrected Heat Rate Validated heat rate corrected to reference conditions
Corrected Heat Rate
Deviation
Difference between reference heat rate and corrected
heat rate.
Heat Rate Deviation Difference between expected heat rate and validated heat
rate
Table 1.2.1. Descriptions of performance calculation categories.
From Table 1.2.1, it is clear that the reference conditions used for the expected and
corrected performance calculations are important since they provide the baseline against
which current performance is measured. A reference conditions data set contains a consistentset of gas turbine performance data.
The performance calculations are more accurate (and more valuable) if the reference data is
accurate and consistent. Reference data usually comes from vendor guarantee data, but it
could also be a data set that the EfficiencyMap user believes to be a highly accurate
representation of the gas turbine conditions for a given point in time. Reference data for the
gas turbine is stored within the turbine.ref file located in the model subdirectory. This
data can be edited using a simple text editor.
The performance calculations are discussed further in Section 2.2 and in conjunction with the
EmapView interface (Section 3).
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2. Eff ic iencyMap Calculat ion CycleAn EfficiencyMap calculation cycle begins when measured data is retrieved from the gas
turbine control system and concludes when EfficiencyMap writes the results to its database
structure. Currently, depending on the computer hardware and processor availability, this
calculation cycle takes about 15 to 30 seconds for each gas turbine. Unit conversions, thermalproperty calculations, data validation, and performance calculations are the major activities
that take place during this calculation cycle, with many intermediate steps between the actions.
In general, each step has a designated executable program that works with a file or set of files
that reside in the EfficiencyMap working directories. For each step to proceed correctly, the
working files (a complete listing of which is contained in Appendix A) must be set up
correctly. This task is performed by a performance engineer before installation of
EfficiencyMap at the plant. The following section describes the files made available for
configuring the operation and outputs of EfficiencyMap1.
2.1 Cross Reference Data Processing
The cross-reference file controls data inputs, outputs, unit conversions, range checking, and
other data processing features.
The cross-reference file name is turbine.csv and typically resides in the
f:\unit#\emap\history subdirectory. Normally, no changes to the values within the cross-
reference file should ever be required. However, understanding the cross-reference file will
lead to a greater understanding of how EfficiencyMap is configured to model a gas turbine.
The cross-reference file specifies to the EfficiencyMap software system:
1. Measured values to be input to EfficiencyMap
2. Output calculated values to be stored in the database
3. Units conversions on measured data
4. Range checking on measured data
5. Averaging of measured values to produce EfficiencyMap input data.
6. Unit conversion of output calculated values
1 Upon installation, all configurations were set up for the users plant. If any modifications are made, be
sure to always back up the file prior to making those changes. If you need assistance and/or reassurance,
please call Enter Software, Inc.
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Figure 2.1.1 Cross-Reference File
The file is comma-delimited and can be most conveniently viewed from within a spreadsheet
program or the codewright file editor. Figure 2.1.1 shows the top-left entries of a typical
cross-reference file.
The cross-reference file contains a horizontal row for every input and output variable (i.e. each
variable that is read in from the plant historian and each calculated variable that is written
back to the plant historian). Each column in the cross-reference file contains information that
controls a feature for a row variable. The following sections describe the seventeen columns
that contain data in the cross-reference file.
Column A (Variable Name), Column B (Tag Name) and Column L (Average Tag)
Column A contains the variable names used within EfficiencyMap while Column B
contains the corresponding tag gathered from the gas turbine control system.
EfficiencyMap variables typically use a from component-to-component notation. For
example, the inlet air temperature comes from the inlet and goes to the gas turbine
component; therefore, a typical variable that appears in the cross-reference file is
INLET1_GT1_TEMP. Measured values are distinguished from validated or calculated
values by adding an _M to the end. For example, INLET1_GT1_TEMP_M is the
measured ambient air temperature, while INLET1_GT1_TEMP is the validated value. It
is not uncommon for the measured value to equal the validated value.
When measured tags are averaged together and the result is placed in one EfficiencyMap
measured variable, the variable names for all but one of those tags are set to ~ (a tilde).All tags to be averaged must be assigned the same tag number in Column L. (Thus, all
tags with tildes in Column A and with the same average tag flag number (the same number
appearing in Column L) are averaged together and assigned to the variable name for that
set in Column A. Averaged tags need not be listed consecutively in the cross-reference file
but are done so to avoid confusion. Note that each set of tags that are averaged together
have a unique number designation in Column L.)
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There are instances in which it is desirable to create a fictitious measured variable when
the measurement does not exist. This is generally the case with a variable like oil fuel
temperature. The data validation is more accurate to assume a reasonable temperature for
the fuel than to assume there is no sensible energy addition to the combustion process. In
these cases, a constant default value is designated through the range checking procedure,
and a ` is placed in Column B for the non-existent measured tag so that EfficiencyMap
will know not to look for a measured tag value.
It is possible to comment out rows in the cross-reference file by making the first character
of the EfficiencyMap variable name in Column A a #. For example, Row 20, #****G1
TAGS**** (Figure 2.1.1) is actually a comment because of the placement of the # at the
start of the line. Commented-out lines are ignored by EfficiencyMap.
Column C (Unit Multiplier), Column D (Unit Offset), Column E (Multiply/Offset
(M/O) Flag), and Column M (Ambient Pressure Flag)
Unit conversions are necessary in order to produce a consistent unit set within the
EfficiencyMap calculations. The multiplier, offset, and multiplier/offset order flags of
columns C, D, and E respectively, control this operation.Column C contains the value that is multiplied by the measured value when the value is
brought into EfficiencyMap. Note that input tags are multiplied by the multiplier during
input operations and output tags are divided by the value in Column C during output
operations. In this way, the same value can be used in Column C for both input and
output variables of the same units. If no conversion is to take place, a 1 appears in
Column C.
Column D specifies the offset applied for unit conversion. Similar to the value in Column
C (the multiplier), the offset is added to input values and subtracted from output values. If
no offset is needed, a 0 is placed in Column D.
Column D also indicates to EfficiencyMap whether or not a pressure offset is to be appliedto a pressure variable. Gauge pressures that come into EfficiencyMap are made absolute
by placing a 99 in Column D. This adds the ambient pressure (specified by a 1 in
Column M) to the measured gage pressure. To convert to absolute from vacuum, a 99 is
used.
Column E is used to indicate the order of multiplier/offset operations. A 0 indicates
that the multiplication operation will occur first, while a 1 indicates that the offset
operation occurs first.
Column F (Range Lower Limit), Column G (Range Upper Limit), Column H (Range
Check Flag), and Column I (Default Value)
The values in these columns control measurement range checking. Columns F and G,respectively, contain the lower and upper limits which define the allowable range for that
variable. Column H is the range check flag, which dictates the action EfficiencyMap will
take for an out-of-range measured variable:
0: no range checking (range checking disabled for the variable)
1: use default value always (the default value is placed in Column I)
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2: an out of range value causes a fatal error (the EfficiencyMap calculation cycle is
aborted)
3: use lower limit if the measured value is below lower limit (value in Column F)
4: use upper limit if the measured value is above upper limit (value in Column G)
5: use lower limit if the measured value is below lower limit, use upper limit if themeasured value is above upper limit
6: leave out of objective function if out of range
>6: Range check flags greater than six designate variables that control the on/off
status of a gas turbine. The range checking functionality for these variables is
obtained by subtracting seven from the value listed.
In order for the EfficiencyMap calculations to function properly, gas turbines that have
been shut down must be detected as being off. Therefore, before each calculation cycle,
the variables that indicate the on/off status for the gas turbine are checked. If all of the
variables that control the status of a gas turbine are out of range, then that gas turbine is
determine to be shut off. Generally, the power is used by EfficiencyMap for this purpose.If EfficiencyMap determines that the gas turbine is off or part-loaded, EmapView will
display O for all performance parameters.
Column J (State Point) and Column K (State Point Type)
The values in these columns designate state points within the plant that require the online
calculation of thermal properties. These points are determine by Enter Software engineers
while developing the data validation model. Normally, the state points are designated by a
temperature and, if needed, a corresponding pressure variable. The required variables are
identified by a unique number or number pair that appears in Column J. For example, if
the specific heat of a gas is needed at a flow location, Column J will identify the
temperature and pressure variables needed for the specific heat look-up with the same
number. The next state point receives a different number or number pair. Column K must
contain the state point flag for the variables that are used to calculate thermal properties.
The state point type identifies the type of flow that is expected for the state point:
1: gas (temperature and pressure required)
2: saturated liquid water (temperature only required)
3: saturated vapor (temperature or pressure required)
4: superheated vapor (temperature and pressure required)
5: oil (temperature only required)
There are many energy balance equations involved with the EfficiencyMap data validationprocess; therefore, specific heats and enthalpies are needed for gas, steam, and fuel flows.
In order to calculate the gas properties, the composition must be known. This information
is obtained by tracing the gas flow path, component by component, and calculating any
changes in composition that occur along the way. Generally, gas turbine combustors and
duct firing are the two locations where composition will change. Once the compositions
have been determined, the measured temperatures are used to calculate the specific heats
and/or enthalpies. The gas composition routines are based on the JANNAF tables.
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Column N (In or Out)
Column N simply, yet critically, designates a variable as an input variable or an output
variable. An I indicates an input variable, an O indicates an output variable.
Column O (MES Section)
The flags in this column control whether or not measured data will be validated. These
values are set by Enter Software and can not be manipulated. The definitions of the
allowable values are as follows:
0: put in objective function
1: set the value in validation calculations
2: do not include in validation calculations
3: put in objective function if greater than zero
Column P (Enthalpy MES Section)
This column controls whether enthalpies, calculated from measured temperatures and/orpressures are placed in the objective function and validated. The allowable values are:
0: put in objective function
1:set the value in data validation calculations
Column Q (Comments)
This column is used to place any comments that are desired.
2.2 Performance Calculations
The performance calculations in EfficiencyMap calculate the current condition and
performance of various plant components. Gas turbine expected power, heat rate corrected tostandard day, and exhaust flow deviation are all examples of the kind of information produced
by the performance module. As previously discussed inSection 1.2, there are five (5) primarytypes of performance calculations for each performance parameter: the calculated
performance based on measured and validated data, expected, corrected to reference,
deviation, and corrected deviation. Most performance calculations are performed in a set for
each of these five types of calculations. By studying the resulting values, the performance of a
component can be monitored over time for specific problems and general degradation.
2.2.1 Calculated Performance
The calculated performance in most cases is simply the validated or measured value of a
particular variable (e.g., gas turbine gross power). In some cases, the calculated performance
is not directly measurable (e.g., gas turbine heat rate) and therefore is calculated directly from
measurements or validated data.
2.2.2 Expected Calculations
The expected performance calculation represents the value that would be produced by a new
and clean component at the current ambient and operating conditions. The expected value is
obtained by taking the reference value (for more on reference values, see Reference Data
section below) and correcting it to the current operating conditions. For example, a gas
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turbines power output will be lower on a hot day. However, it is not obvious to a plant
operator whether the lower power production is solely due to the hotter weather or a
combination of the ambient air temperature and gas turbine performance degradation. The
expected power removes the effect that the current ambient conditions have on output and
provides information that can be used for diagnosis. The expected deviation is the difference
between the expected value and the validated value. A large deviation can indicate a serious
performance problem.
2.2.3 Corrected to Reference Calculations
Technically, a Corrected to Reference calculation is the inverse of the expected value
calculation. The component performance is determined from validated and/or measured data
and then this performance is corrected back to reference conditions. Returning to the gas
turbine example above, the Corrected to Reference value would be the result of taking the
validated power produced at the current ambient temperature and then correcting the power to
the cooler reference temperature. The result is an additional indication of component
degradation. If the component functions as new, the Corrected to Reference value should be
very close to the reference performance and not vary much over time and changing conditions.
However, as the component ages, the Corrected to Reference value will decrease, indicating adrop in performance.
The performance functions use a variety of information to carry out their calculations. In
every case though, current and reference values are required. The current values can be taken
from either the DCS measured values or, preferably, from the EfficiencyMap validated data
set. Often, the same functions are performed with each of these data sets in order to observe
the effects of the data validation.
2.2.4 Reference Data
As discussed previously, the reference data are vitally important to the accuracy and value of
the expected and corrected performance calculations. The reference data are stored in a file
named TURBINE.REF in the MODEL sub-directory. The file contains a header named
[HEAT BALANCE] under which the reference data set is recorded. The data associates the
reference value with its EfficiencyMap variable name. It is important to note that this is a
consistent set of data, meaning that the data represents the gas turbine at a specific operating
condition. Typically the reference operating condition is the guarantee data provided by the
vendor. Changes should not be made to this file without consulting Enter Software.
2.2.5 Performance Example
Most performance calculations are performed through the application of a series of correction
factors. These correction factors come from vendor curves and correlations developed by
Enter Software. The general format of a typical set of performance functions can be illustrated
by calculating a gas turbines power: expected, Corrected to Reference (CREF), and deviation.
For simplicity, assume that the gas turbine power is only a function of the air inlet temperatureand pressure. The required input data are:
GT reference power = 100.0 MW
reference air inlet temperature = 59.0 oF
reference air inlet pressure = 14.696 psia
current GT power = 102.0 MW
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current air inlet temperature = 35.0 oF
current air inlet pressure = 14.3 psia
From this information, the correction factors can be obtained from vendor curves or other data.
Figure 2.2.1 is an example of vendor correction curves.
Figure 2.2. 1 GT Correction Curve
For this example, the correction factors would be as follows:
correction factor for the reference air inlet temperature = 1
correction factor for the reference air inlet pressure = 1
correction factor for the current air inlet temperature = 1.08
correction factor for the current air inlet pressure = .97
The three gas turbine performance power values would then be:
GT expected power = (reference power) * (current CF) / (reference CF)
GT expected power = 100 * (1.08 * .97) / ( 1.0 * 1.0 * 1.0)
GT expected power = 104.8 MW
GT power deviation = expected power - validated power
GT power deviation = 104.8 102.0
GT power deviation = 2.8 MW
GT power CREF = (validated power) * (reference CF) / (current CF)
GT power CREF = 102 * (1.0 * 1.0) / (1.08 * .97 )
GT power CREF = 97.4 MW
The corrected deviation calculation shows that for this set of circumstances
Gas turbine power correction for inlet temperature
Air Inlet Temperature (F)
correction factor
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GT power CREF Dev= (reference power) - GT power CREF
GT power CREF Dev= 100 97.4
GT power CREF Dev=2.6 MW
that this particular gas turbine has degraded 2.6 MW from its guarantee reference conditions.
Some performance calculations use general engineering equations to obtain their results. Thegas turbine compressor and turbine efficiency functions use the isentropic efficiency definitions
of:
compressor efficiency = (inlet enthalpy - outlet enthalpy) / (inlet enthalpy - isentropic exit
enthalpy)
turbine efficiency = (inlet enthalpy - isentropic exit enthalpy) / (inlet enthalpy - exit
enthalpy)
EfficiencyMap enthalpies are accurately calculated using routines based on JANNAF tables.
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3. EmapView
3.1 EmapView
The EmapView program is a graphical interface that allows the user to view the current
snapshot of measured, validated, and performance data that lies within EfficiencyMap. Thissection will introduce the data forms available in the interface, provide an overview of their
general features, and give some advice on how to interpret the information presented.
It is important to note that the standard Simple Cycle EfficiencyMap will display zeros for all
performance calculations if the gas turbine is not operating on its baseload control curve.
EfficiencyMap can be configured to calculate performance values for partload operation. If
you desire this enhancement please contact Enter Software Inc.
Figure 3.1.1 shows the EmapView main window. This window is activated by double-clicking
on the EmapView icon in the EfficiencyMap program group box within the Windows NT
Program Manager. The interface functions like other windows in that it can be minimized,
restored, closed, moved, and resized.
Figure 3.1.1 EmapView Main Window
The status bar at the bottom of the interface contains two information boxes that provide
critical information. The box on the left displays the message Mode: Online. indicating that
the current operating mode of EfficiencyMap is Online. The middle box contains the current
time stamp associated with the EfficiencyMap calculation cycle. This timestamp indicates the
moment when the measured data was retrieved from the DCS and therefore the moment to
which all the validated and performance data applies.
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All of the EmapView data forms are accessed via the View pull down item. Pulling down
View, as shown in Figure 3.1.2, reveals that there are four options available:
Components, Performance Report, Sensor Report and Error Log. Selecting the,
Performance Report or Sensor Report option will bring up a form of the same name. The
last option, Error Log, will start a text window that displays the EfficiencyMap Error Log.
Figure 3.1.2 "View" Pull Down MenuThese forms are described in detail in the following section. Selecting the Components
option will cause the gas turbine component sub-menu to appear (Figure 3.1.3).
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Figure 3.1.3 Components Sub-menu
3.2 EmapView Performance Report and Sensor Report
FormsThe two summary form options available under the View pull-down menu are the
Performance Report and Sensor Report. These forms display EfficiencyMap summaryinformation and are important diagnostic tools.
3.2.1 Performance Report
The Performance Report displays and sorts the validated and expected performance values for
selected parameters (Figure 3.2.1). The Performance Report sorts the information by either
the parameter description or the percent deviation between the validated and expected
performance for the particular parameter.
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Figure 3.2. 1 Performance Report
This report allows the user to quickly determine which parameters vary from their expected
values the most. By viewing the percent deviation of the parameters validated value from its
expected value, one can quickly determine problem areas in gas turbine performance. This
report highlights the most deviant plant parameters by sorting the percent deviations of the
parameters in descending order. The list of parameters may also be sorted by description toallow for quick location of a parameter and its data.
3.2.2 Sensor Report
The Sensor Report form (Figure 3.2.2) presents a sorted comparison between gas turbine
measured data and the EfficiencyMap validated values. It is helpful in diagnosing measured
tags that for various reasons (e.g., malfunctioning transducers) are not functioning properly.
All of the gas turbine values that are validated by EfficiencyMap are displayed.
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Figure 3.2. 2 Sensor Report
Each row in the Sensor Report contains a description, tag name, units, the percent uncertainty
assigned to this measurement, the measured and validated values, and the percent deviation
between the measured and validated value. The rows may be sorted by the parameters
description, percent uncertainty, or by the percent deviation. The sensor report is valuable in
that it allows one to quickly pinpoint faulty plant measurements. Parameters which show asignificant deviation between the measured and validated values may indicate a problematic
measurement, due to a faulty or miscalibrated sensor. If the measured value and the validated
value are exactly the same, then the data validation model has been configured to use the
measured value directly in the gas turbine heat balance model.
3.2.3 Error Log
This last option under the View pull-down menu starts a display box that loads the current
EfficiencyMap error log file. The error log records any errors or warnings that occur during
the EfficiencyMap calculation cycle. The display box also allows the user to erase the current
information in the error log by clicking on the Erase button.
3.3 EmapView Gas Turbine Data FormThis section discusses the features of the EmapView Gas Turbine form.
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Figure 3.3. 1 Gas Turbine Design & Thermal Data
When GT1 (note: even with multiple gas turbines at the site, the gas turbine component
selection is always GT1) is selected from the View pull-down menu, the component form
automatically comes up with the first page of Performance Data displayed. The Gas Turbine
component form actually provides access to several forms that can be split into three
categories: Design and Thermal Data, Performance Data, and Heat Balance Data. For each
plant component, there is one Design and Thermal Data form. There can be several
Performance Data and Heat Balance Data forms. The Gas Turbine Design & Thermal Dataform is shown in Figure 3.3.1. Note that at the top of the form there is a frame containing
option buttons for switching between the Design and Thermal Data form, the Performance
Data forms, and the Heat Balance Data. This frame appears at the top of all the component
data forms and allows the user to toggle between the data displays. Clicking on an option
button next to a form name selects that form and makes it active.
The information presented in the Design and Thermal Data form (Figure 3.3.1) is broken into
Design Parameters and Thermal Data. The Design Parameters are important constants
used in the heat balance model. The thermal data consists of thermodynamic property data,
such as enthalpies and specific heats, calculated from the measured plant data.
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Figure 3.3.2 Gas Turbine Performance Data (I)
Figure 3.3.2 shows the first of three Performance Data forms that exist for the gas turbine
component. This form displays the results from the performance calculations and also some of
the validated and measured data. The emphasis is to provide information for comparison. The
row names indicate the calculated variable and its units. In the case of Figure 3.3.2, the gas
turbine Gross Power, Gross LHV Heat Rate, Fuel Flow, Compressor Efficiency, and
Expander Efficiency are presented. The number of rows on a Performance Data form may
vary depending on the component and Performance Data form number (some components aremore complex, others less, which affects the amount of information available to display).
There are always seven identically named columns presented on a Performance Data form as in
Figure 3.3.2. The following list defines the column names.
Reference
This column contains the reference value for the parameter.
Measured
This column contains the measured (or calculated from measured) value obtained from
the DCS for the particular parameter.
Validated
This column contains the heat balance validated value for the parameter.
Expected
This column contains the expected value for the parameter. This is the parameters
expected value given the current validated operating conditions, and uses the reference
value adjusted to current conditions. Operating conditions for the gas turbine are
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defined as ambient temperature, pressure, and humidity, and guide vane angle
setting.
Corrected to Ref.
This column contains the corrected value for the parameter. The corrected value is the
validated value corrected to reference conditions. This calculation indicates the
parameter value that would be expected if the plant, in its current state, were to
operate at reference conditions.
Current Dev
The Current Deviation column contains the calculated deviation between calculated
expected value and the calculated validated value. Ideally, the heat balance results
would equal the reference parameter values. The Current Deviation calculation,
therefore, is an indication of how closely the plant or component is meeting expected
performance.
CREF Dev
The Corrected Deviation column contains the calculated deviation between thecorrected value and the reference value. Ideally, the current heat balance results, when
corrected to reference conditions, would equal the reference parameter values. The
Corrected Deviation calculation is an additional check that summarizes how closely
current plant or component performance is to the reference performance.
For a more detailed discussion on performance parameters, please see Section 2.2
Performance Calculations.
There is also a color code associated with the results displayed on the data forms. There are
four possible colors for the table entries on the Performance Data and Heat Balance Data
forms:
1. A grayed out table entry.
If there is no value for a particular calculation, measurement, reference value, or
uncertainty, the table entry is grayed out (for example, the measured expander
efficiency in Figure 3.3.3).
2. A black number or variable name.
All numbers and variable names on the Component Diagram and Design and Thermal
Data forms are black. In addition, all reference values on the Performance Data forms
and all uncertainty entries on the Heat Balance Data forms are colored black. Black
indicates values that are relatively static in the model (i.e., normally they do not change
from one EfficiencyMap calculation cycle to the next).
3. A blue number.Blue numbers occur on the Performance Data and Heat Balance Data forms. Blue
numbers represent measured and calculated numbers. Blue values typically change
from run to run and are dependent on plant operation and environmental conditions.
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4. A red number.
Red numbers can occur for any measured values on the Performance Data and Heat
Balance Data forms. A red number indicates that a raw measured value did not pass
the range checking test and was replaced with a default value.
The final type of component data form used to view the current snapshot within EfficiencyMap
is the Heat Balance Data form. In the case of the gas turbine, there are three data forms.
Figure 3.3.3 shows the first form (Heat Balance Data (I)).
Figure 3.3. 3 Gas Turbine Heat Balance (I)
The Heat Balance Data form displays five columns of information for each parameter listed.
The five columns summarize the vital information that is associated with the current heat
balance calculation. The first column lists the measured value for the parameter. This is the
measured value the EfficiencyMap has brought in from the DCS. The second column is the
uncertainty percentage assigned to the measured value. The next two columns are the
optimization simple constraint values. The minimum value provides the lower bound that a
heat balance validated parameter value may take. The maximum value provides the upper
bound. The final column lists the heat balance validated value for the parameters. Note that a
grayed out entry (as discussed previously) indicates that there is no value for that field, for that
parameter. If the measured value field is gray, then the parameter has no measurement fromthe DCS. If any uncertainty field is gray, then the parameter was not validated in the heat
balance model, and thus, its validated value will equal the measured value. A gray field for the
range values (Minimum and Maximum) indicates that the parameter does not need any simple
bounds within the validation model.
This review of the Gas Turbine Component forms has covered the characteristics of the data
forms that are used for the gas turbine and the other components. There are four Gas Turbine
Component forms that have not been shown in this user guide: the Performance Data forms
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(II) and (III) and the Heat Balance Data forms (II) and (III). Time should be taken to view
these forms so that the user can become familiar with the locations of each of the component
parameters that are displayed.
4. Appl icat ion Examples
4.1 Applying EfficiencyMap
This Section contains examples of EfficiencyMaps application in analyzing and diagnosing
gas turbine and bottoming cycle performance. These examples provide guidance in applying
the program by showing how EfficiencyMap has been used and the benefits of its application.
This section displays several plots that were created using the techniques discussed in the
previous section.
4.2 Validated Vs. Measured Fuel Flow
Performance parameters computed from the heat balance validated data are more complete and
more accurate than parameters computed from measured data.. Figure 4.2.1 compares
measured and validated engine heat rate data for a generic gas turbine engine.
Measured and Calculated Heat Rate vs Power
10950
11000
11050
11100
11150
11200
11250
11300
11350
11400
11450
11500
33 34 35 36 37 38 39
Power (MW)
HeatR
ate
HRmes
HRcalc
Figure 4.2.1 Heat Rate data for a generic gas turbine engine. Measured data taken at 15
minute intervals over a five day period. Fuel sensor has been recalibrated
The measured heat rate (HRmes) on Figure 4.2.1 was calculated by dividing the measured fuel
flow by the measured power. The calculated heat rate was calculated by dividing the
EfficiencyMap validated value for fuel flow by the validated power. Note that the validated
heat rate has a smaller scatter than the measured heat rate. It appears that the measured heat
rate has a spread of approximately 150 Btu/Kw-hr, while the heat balance heat rate shows a
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spread of only 25 Btu/Kw-hr. The conclusion is that even when fuel flow and power are
measured quite accurately (this plant had recently recalibrated the fuel flow sensors),
EfficiencyMap is able to improve the accuracy of the data by using mass and energy balance
methods.
It is easy to understand how the validated fuel flow can be more accurate than the measured
fuel flow. It is possible to calculate fuel flow from the EfficiencyMap gas turbine equationsusing inlet temperature, inlet pressure, compressor discharge temperature, compressor
discharge pressure, exhaust temperature, exhaust pressure, and power as inputs. These
measured parameters typically are accurate to within one percent. The measured fuel flow,
however, is often accurate to only three percent or worse. Thus, fuel flow calculated from the
measured temperatures, pressures, and power may be more accurate than the measured fuel
flow.
In effect, though, EfficiencyMap uses both the measured fuel flow and the other measured
parameters in its determination of validated fuel flow. For example, if the measured fuel flow
is greater than the fuel flow that would be calculated from the other engine data (measured
temperatures, pressures, and power), EfficiencyMap could only change the measured fuel flow
downward until the EfficiencyMap validated value for fuel flow exactly matches the fuel flowvalue that would be calculated from the other engine data. However, in reality, the validated
fuel flow is free to decrease and the other parameters (e.g., power and exhaust temperature) are
free to increase in order to achieve a heat balance.
The amount that EfficiencyMap adjusts the fuel flow relative to the adjustment in the other
parameters (such as exhaust temperature) depends upon the relative uncertainties assigned (by
the user) to each measured parameter. If fuel flow has an uncertainty of 10% and exhaust
temperature has an uncertainty of 1%, the adjustment in fuel flow will be larger than the
adjustment in exhaust temperature.
If sufficient redundancy exists in the plant measurements, EfficiencyMap is fully capable of
diagnosing which measurement is not accurate. For example, if fuel flow is measured too high
and all the other measurements are accurate, EfficiencyMap will apply almost all of theadjustment to the fuel flow because to change some other parameter (such as exhaust
temperature) would cause further errors in the heat balance calculation. If exhaust
temperature were increased instead of fuel flow being decreased, then an error in the HRSG
energy balance would be introduced. This would force EfficiencyMap to change other HRSG
measurements such as stack temperature and steam flows.
Fortunately, the optimization techniques in EfficiencyMap forces the analysis to make the
minimum changes necessary to achieve an energy balance. Changing a single parameter such
as fuel flow is preferred over changing many parameters (e.g., exhaust temperature, steam
flows, and stack temperature), unless the user forces the analysis not to change fuel flow by
inputting a very low fuel flow uncertainty relative to the uncertainties in the other
measurements.
This method is very useful for correcting poor measurements as well as for improving good
ones. Figure 4.2.2 shows a comparison of measured and validated heat rates for the same
generic engine illustrated in Figure 4.2.1. However, this data was taken over a two day period
before the fuel sensor was recalibrated. Notice that the measured heat rate values do not
change in the expected manner in relation to power and show a scatter of nearly 700
Btu/kWhr. The validated heat rate values agree with the data of Figure 4.2.1 to within 50
Btu/kWhr and show a scatter of approximately 50 Btu/kWhr.
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Measured and Calculated Heat Rate vs Power
10400
10600
10800
11000
11200
11400
11600
11800
33 34 35 36 37 38 39
Power (MW)
HeatRate
HRmes
HRcalc
Figure 4.2.2 Measured and calculated heat rates
4.3 Validated Compressor and Expander Efficiencies
The value of expander efficiency is a sensitive indicator of the accuracy of the heat balance
fuel flow, air flow, firing temperature, and power values. This value is computed by
EfficiencyMap. Expander efficiency is a sensitive parameter because it depends upon an
EfficiencyMap heat balance expander inlet gas temperature (turbine inlet temperature). Thissensitivity is further caused by the dependency of the turbine inlet temperature upon heat
balance and validated values of engine air flow, power, and fuel flow2. If any of these
calculations are incorrect, the turbine inlet temperature will be inaccurate, in which case the
expander efficiency (which is expected to remain fairly constant) will show unexpected
variations.
2 Here, the name heat balance is used to distinguish EfficiencyMap variables that appear in the heat
balance equations from those that appear in the heat balance equations and have measuredcounter parts.
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Compressor and Expander Efficiencies vs Time
87
88
89
90
91
92
93
0 100 200 300 400 500 600
Time Increment (15 min each)
Efficiency
EFFC
EFFT
Figure 4.3.1 Calculated compressor and expander efficiencies
Figure 4.3.1 shows EfficiencyMap heat balance values for compressor and expander
efficiencies. The scatter in the data indicates that EfficiencyMap can determine these
efficiencies to within one-quarter to one-half percent. In particular, note the small variations in
expander efficiency which indicates that engine validated fuel flow, power, air flow, and firing
temperature must be calculated accurately.
4.4 Tracking Compressor Efficiency Improvementsfrom Online and Off-line Washes
This example is an introduction to the use of EfficiencyMap to track and monitor compressor
performance.
Figure 4.5.1shows the validated and corrected compressor efficiencies for a gas turbine over a
period of time during which two online water washes and one off-line compressor (crank) wash
were performed. The corrected compressor efficiency is EfficiencyMaps Performance
modules estimate of the compressor efficiency if the engine were operating at reference
conditions.
Each of the two online washes (performed at approximately 40 and 65 hours on the plot)appears to increase corrected efficiency by a small amount. These increases are not apparent
in the validated compressor efficiency.
Both the validated and corrected compressor efficiencies increase approximately one percent
when the off-line wash is performed at 100 hours into the trend. However, the validated
compressor efficiency degrades nearly one percent when the weather turns colder after the
crank wash (starting at approximately 150 hours). If an operator were watching the validated
compressor efficiency only, he would be in danger of concluding that the improvement due to
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the wash had lasted for less than 100 hours. However, the corrected compressor efficiency,
which accounts for changes in compressor efficiency as environmental and operating
conditions change, does not measurably change over the 100 hour period.
The engine heat rate improved approximately two percent at the time of the off-line wash and
remained constant for 100 hours thereafter. Theoretically, one could simply monitor the engine
heat rate to evaluate compressor efficiency. However, since fuel flow is often measured at lessthan two percent accuracy, the measured engine heat rate is not accurate enough to detect a one
percent change in compressor efficiency. The compressor efficiency can be calculated more
accurately than heat rate because it depends upon measured temperatures and pressures, which
are usually measured more accurately than fuel flows. However, the compressor efficiency
must be corrected in order to be useful.
EfficiencyMap accurately reports both corrected compressor efficiency and validated engine
heat rate so that either one or both may be used to evaluate engine condition.
Figure 4.4.1 Corrected and Validated Compressor Efficiencies
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5. Appendices
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Appendix A. EfficiencyMap File Structure
There are two main directories that contain the files necessary for EfficiencyMap operation.
The EfficiencyMap configuration files reside in several sub-directories contained in the
Unit# directory. The EfficiencyMap executables reside in the EMAP directory that is
located off the root of the hard drive. The following descriptions outline this file structure in
more detail.
UNIT DIRECTORY: UNIT #
DATA : storage location for input and output data files
ASCII contains both the EfficiencyMap comma delimited input (measured data andconstants) and output (EfficiencyMap) files, respectively named IN.CSV and
OUT.CSV.
INTERFACE : files used to configure interface and data files for display
The three interface configuration files are named TRB_GT.CFG (gas turbine
component form configuration, TRB_PRPT.CFG (performance report form
configuration), and TRB_SENS.CFG (sensor report form configuration).
There are also copies of the TURBINE.HB, TURBINE.MES, and
TURBINE.RAW files. These files are copied from the HISTORY directory at
the end of each EfficiencyMap calculation cycle.
MODEL : EfficiencyMap configuration files
TURBINE.EQN : equation file, contains the mass & energy balance
TURBINE.HDR : header file
TURBINE.INT : initial guess file
TURBINE.MDL : gas turbine model file
TURBINE.PRF : performance configuration file
TURBINE.REF : reference values file
TURBINE.TBL : gas turbine performance tables file
STDTABL.TXT : standard tables
HISTORY : data files used for running EfficiencyMap
TURBINE.HB : heat balance and performance values
TURBINE.HIS : history mode plant configuration file
TURBINE.LOG : Lingo output file
TURBINE.LNG : Lingo input file
TURBINE.MES : input measured data
TURBINE.OUT : Lingo output file
TURBINE.RAW : unprocessed input data
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TURBINE.UNC : objective function uncertainties
THERMAL.PRF : used by Perf.exe to calculate GT airflows
TURBINE.CSV : online mode cross reference file
EMAP : executables
Extract.exe : data acquisition
HtoT.exe : converts enthalpies to temperatures
Performance.exe : calculates performance functions
HB.exe : communicates between EfficiencyMap and Lingo
Emap.exe : online mode executable
Emapview.exe : EmapView interface executable
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Appendix B. Variable Name Descriptions
Tagname Description Units Value
AIR_INLET1_PRES_M Ambient Pressure in Hg 14.59223
AIR_INLET1_RH_M Relative Humidity 0-100 60.0
GT1_CDP Compressor Discharge Pressue Validated PSIG 168.9878
GT1_CDP_M Compressor Discharge Pressure PSIG 0.004070544
GT1_CDT Compressor Discharge Temperature Validated F 663.9897
GT1_CDT_M Compressor Discharge Temperature 2 F 663.9897
GT1_COMPEFF Compressor Efficiency Validated % 88.77342
GT1_COMPEFF_CSTD Compressor Efficiency Corrected % 11.70192
GT1_COMPEFF_CSTD_DEV Compressor Efficiency Corrected Deviation % 89.20089
GT1_COMPEFF_DEV Compressor Efficiency Deviation % -0.697525
GT1_COMPEFF_EXP Compressor Efficiency Expected % 88.77342
GT1_COMPEFF_M Compressor Efficiency Measured % 88.77644
GT1_HRGRSLHV Gross Heat Rate (LHV) Validated Btu/kWh 9968.391
GT1_HRGRSLHV_CSTD Gross Heat Rate (LHV) Corrected Btu/kWh 10138.89
GT1_HRGRSLHV_CSTD_DEV Gross Heat Rate (LHV) Corrected Deviation Btu/kWh 1381.106
GT1_HRGRSLHV_DEV Gross Heat Rate (LHV) Deviation Btu/kWh 1357.882
GT1_HRGRSLHV_EXP Gross Heat Rate (LHV) Expected Btu/kWh 11326.27
GT1_HRGRSLHV_M Gross Heat Rate (LHV) Measured Btu/kWh 9968.391
GT1_IGV_M DEG 84.29836
GT1_INDP Inlet Pressure Drop Validated in H2O 84.29836
GT1_INDP_CSTD Inlet Pressure Drop Corrected in H2O 3.598278
GT1_INDP_CSTD_DEV Inlet Pressure Drop Corrected Deviation in H2O 0.401722
GT1_INDP_DEV Inlet Pressure Drop Deviation in H2O 0.4689002
GT1_INDP_EXP Inlet Pressure Drop Expected in H2O 4.2
GT1_INDP_M Inlet Pressure Drop Measured in H2O 4.2
GT1_OUTDP Outlet Pressure Drop Validated in H2O 0.55
GT1_OUTDP_CSTD Outlet Pressure Drop Corrected in H2O 9.615911
GT1_OUTDP_CSTD_DEV Outlet Pressure Drop Corrected Deviation in H2O 7.628142
GT1_OUTDP_DEV Outlet Pressure Drop Deviation in H2O -3.312994
GT1_OUTDP_EXP Outlet Pressure Drop Expected in H2O 6.302917
GT1_OUTDP_M Outlet Pressure Drop Measured in H2O 9.615911
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GT1_OUTLET1_FLOW Exhaust Flow Validated KPPH 0.000256962
GT1_OUTLET1_FLOW_CSTD Exhaust Flow Corrected KPPH 2031.4
GT1_OUTLET1_FLOW_CSTD_DEV Exhaust Flow Corrected Deviation KPPH 1952.302
GT1_OUTLET1_FLOW_DEV Exhaust Flow Deviation KPPH -110.4011
GT1_OUTLET1_FLOW_EXP Exhaust Flow Expected KPPH 1920.999
GT1_OUTLET1_PRES_M Outlet Pressure Drop in H2O 14.9384
GT1_OUTLET1_TEMP Exhaust Temperature Validated F 14.9384
GT1_OUTLET1_TEMP_CSTD Exhaust Temperature Corrected F 1050.759
GT1_OUTLET1_TEMP_CSTD_DEV Exhaust Temperature Corrected Deviation F 1039.242
GT1_OUTLET1_TEMP_DEV Exhaust Temperature Deviation F -75.91736
GT1_OUTLET1_TEMP_EXP Exhaust Temperature Expected F 1039.242
GT1_OUTLET1_TEMP_M Exhaust Temperature F 1039.242
GT1_PWRCMP Compressor Power MW 85.56175
GT1_PWRGRS Power MW 85.56175
GT1_PWRGRS_CSTD Power Corrected MW 79.07307
GT1_PWRGRS_CSTD_DEV Power Corrected Deviation MW 73.77074
GT1_PWRGRS_DEV Power Deviation MW -23.8929
GT1_PWRGRS_EXP Power Expected MW 55.18016
GT1_PWRGRS_M Power Measured MW 79.07307
GT1_PWRTRB Expander Power MW 166.2486
GT1_TCOMB Combustor Outlet Temperature F 2158.005
GT1_TFIRE Firing Temperature F 2086.965
GT1_TIT Turbine Inlet Temperature F 2027.64
GT1_TURBEFF Expander Efficiency Validated % 2027.64
GT1_TURBEFF_CSTD Expander Efficiency Corrected % 2027.64
GT1_TURBEFF_CSTD_DEV Expander Efficiency Corrected Deviation % 89.32154
GT1_TURBEFF_DEV Expander Efficiency Deviation % 89.32154
GT1_TURBEFF_EXP Expander Efficiency Expected % 89.2
GT1_WCOOL Total Cooling Flow KPPH 179.0017
GT1_WROTOR Rotor Cooling Flow KPPH 81.44579
GT1_WVANE Vane Cooling Flow KPPH 97.55595
H2O_GT1_FLOW_M H2O Injection Flow lbm/s 97.55595
INLET1_GT1_FLOW Inlet Flow Validated KPPH 1988.908
INLET1_GT1_FLOW_CSTD Inlet Flow Corrected KPPH 1911.465
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INLET1_GT1_FLOW_CSTD_DEV Inlet Flow Corrected Deviation KPPH -97.23486
INLET1_GT1_FLOW_DEV Inlet Flow Deviation KPPH -101.1743
INLET1_GT1_FLOW_EXP Inlet Flow Expected KPPH 1988.908
INLET1_GT1_PRES_M Inlet Pressure Drop in H2O 14.44103
INLET1_GT1_RH_M Relative Humidity 0-100 0
INLET1_GT1_TEMP_M Inlet Temperature 2 F 70.1
NGFUEL_GT1_FLOW Gas Fuel Flow Validated lbm/s 0
NGFUEL_GT1_FLOW_CSTD Gas Fuel Flow Corrected lbm/s 0
NGFUEL_GT1_FLOW_CSTD_DEV Gas Fuel Flow Corrected Deviation lbm/s 0
NGFUEL_GT1_FLOW_DEV Gas Fuel Flow Deviation lbm/s 0
NGFUEL_GT1_FLOW_EXP Gas Fuel Flow Expected lbm/s 0
NGFUEL_GT1_FLOW_M Gas Fuel Flow Measured lbm/s 0
NGFUEL_GT1_TEMP_M Gas Fuel Temp F 0
OILFUEL_GT1_FLOW Oil Fuel Flow Validated lbm/s 0.0004
OILFUEL_GT1_FLOW_CSTD Oil Fuel Flow Corrected lbm/s 42.49225
OILFUEL_GT1_FLOW_CSTD_DEV Oil Fuel Flow Corrected Deviation lbm/s -8.350939
OILFUEL_GT1_FLOW_DEV Oil Fuel Flow Deviation lbm/s -8.80032
OILFUEL_GT1_FLOW_EXP Oil Fuel Flow Expected lbm/s 33.69193
OILFUEL_GT1_FLOW_M Oil Fuel Flow Measured lbm/s 42.49225
OILFUEL_GT1_TEMP_M Oil Fuel Temp F 0
SYSTEM_PAMB_M Ambient Pressure in Hg 14.59223
SYSTEM_RHAMB_M Relative Humidity 0-100 0
SYSTEM_TAMB_M Ambient Temp F 70.1