RKI Eagle 2 Operator's Manual

Eagle 2 Data Logger
Management Program
Operator’s Manual
Part Number: 71-0170RK
Revision: C
Released: 6/12/12
www.rkiinstruments.com
Warranty
RKI Instruments, Inc. warrants gas alarm equipment sold by us
to be free from defects in materials and workmanship, and
performance for a period of one year from date of shipment from
RKI Instruments, Inc. Any parts found defective within that
period will be repaired or replaced, at our option, free of charge.
This warranty does not apply to those items which by their
nature are subject to deterioration or consumption in normal
service, and which must be cleaned, repaired, or replaced on a
routine basis. Examples of such items are:
Absorbent cartridges
Batteries
Pump diaphragms and valves
Filter elements
Fuses
Warranty is voided by abuse including mechanical damage,
alteration, rough handling, or repairs procedures not in
accordance with the instruction manual. This warranty indicates
the full extent of our liability, and we are not responsible for
removal or replacement costs, local repair costs, transportation
costs, or contingent expenses incurred without our prior
approval.
This warranty is expressly in lieu of any and all other warranties
and representations, expressed or implied, and all other
obligations or liabilities on the part of RKI Instruments, Inc.
including but not limited to the warranty of merchantability or
fitness for a particular purpose. In no event shall RKI
Instruments, Inc. be liable for indirect, incidental, or
consequential loss or damage of any kind connected with the
use of its products or failure of its products to function or operate
properly.
This warranty covers instruments and parts sold to users only by
authorized distributors, dealers, and representatives as
appointed by RKI Instruments, Inc.
We do not assume indemnification for any accident or damage
caused by the operation of this gas monitor and our warranty is
limited to replacement of parts or our complete goods.
Warranty
Table of Contents
Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
System Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
Installing the Eagle 2 Data Logger Management Program . . . . . . . . . . 3
IrDA Downloading Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Installing an IrDA Adapter Cable . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Windows® Wireless Link Operation Note . . . . . . . . . . . . . . . . . . . . . 6
Launching the Program . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Control Buttons . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
Download Button . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Instrument Information Button . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Data Button . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11
Last Calibration Button . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
Set Button . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
Downloading Data from the Eagle 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Eagle 2 Data Logging Capacity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
Overwriting Data in the Eagle 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
Viewing Data in the Instrument Information Screen . . . . . . . . . . . . . . 22
Viewing, Printing, Exporting, & Deleting Data in the Data Window . . 24
Data Window . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
Calibration History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26
Event Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
Interval Trend Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
Alarm Trend Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 50
Deleting Data in the Data Window . . . . . . . . . . . . . . . . . . . . . . . . . . 60
Table of Contents
Changing the Password . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
Viewing, Printing, & Deleting Data in the Last Calibration Window . . 66
Viewing & Printing Last Calibration Data . . . . . . . . . . . . . . . . . . . . . 66
Deleting Last Calibration Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
Calibrating An Eagle 2 With the Data Logging Software . . . . . . . . . . 73
Changing Eagle 2 Instrument Parameters . . . . . . . . . . . . . . . . . . . . . . 77
Detail Settings Button. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80
Station & User Tab . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82
Conversion Table Tab . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88
PID Sensor Tab . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94
Obtaining a Relative Response Factor . . . . . . . . . . . . . . . . . . . . . 101
Changing the Appearance of the Program Screens . . . . . . . . . . . . . .113
Spare Parts List . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .116
CAUTION: Read and understand this manual before using the
Eagle 2 Setup Program. Also read and understand
the Eagle 2 Operator’s Manual included with the
Eagle 2 portable gas detector.
Table of Contents
Introduction
Using an advanced detection system consisting of up to six gas
sensors, the Eagle 2 Gas Monitor detects the presence of
combustible gases, oxygen (O2), carbon monoxide (CO),
hydrogen sulfide (H2S), and 2 other gases simultaneously. The
Eagle 2’s compact size and easy-to-use design make it ideally
suited for a wide range of applications as described in the Eagle
2 Operator’s Manual. Please read the Eagle 2 Operator’s
Manual first before using the Eagle 2 Data Logger Management
Program.
The Eagle 2 Data Logger Management Program downloads
stored data in the Eagle 2 to a Windows-based PC. After the
data has been downloaded, you can view, save, or print it using
your computer and the Eagle 2 Data Logger Management
Program.
The purpose of this manual is to explain how to use and set up
the Eagle 2 Data Logger Management Program. You will learn
how to:
• install and launch the program
• install the downloading cable (if needed)
• download data from the Eagle 2
• view, print, and save data
• change data logging parameters
• perform a calibration
• change the appearance of the program screens
• change the color of graphed readings for a particular gas
Before you get started, be sure to review the system
requirements in the next section.
Introduction • 1
CAUTION: The Eagle 2 detects oxygen deficiency and
elevated levels of oxygen, combustible gases,
carbon monoxide, and hydrogen sulfide, all of
which can be dangerous or life threatening. When
using the Eagle 2, you must follow the instructions
and warnings in the Eagle 2 Operator’s Manual to
assure proper and safe operation of the unit and to
minimize the risk of personal injury.
CAUTION: The operator of this instrument is advised that if the
equipment is used in a manner not specified in this
manual, the protection provided by the equipment
may be impaired.
System Requirements
To use the Eagle 2 Data Logger Management Program , your
personal computer must meet the following requirements:
• Operating Systems: Windows® 2000, Windows® XP,
Windows® Vista, or Windows® 7.
• Processor: IBM® compatible PC running Pentium® 2 or
higher.
• Memory: 32 MB RAM minimum
• Available Hard Disk Space: 32 MB minimum
• CD-ROM Drive
• Infrared port or
USB port and a USB/IrDA adapter cable
2 • System Requirements
Installing the Eagle 2 Data Logger
Management Program
1. Launch Windows®.
2. Exit from all applications and open windows.
3. There are two ways to install the Eagle 2 Data Logger
Management Program: by using the Eagle 2 Product CD or
by using the Eagle 2 Data Logger Management Program
Installation CD.
• If you are using the Eagle 2 Product CD, insert the Product
CD in your computer’s CD-ROM drive. The CD will
automatically open revealing several folders. Open the
Data Downloading Program folder, double click on
setup.exe, then continue with step 4.
• If you are using the Eagle 2 Data Logger Management
Program Installation CD, it will automatically begin the
installation process. Insert it in your computer’s CD-ROM
drive, then continue with step 4.
4. After a few seconds, a screen appears indicating that the
InstallShield Wizard is preparing to install the Data Logger
Management Program, then the Eagle 2 InstallShield Wizard
window appears to guide you through installation.
Installing the Eagle 2 Data Logger Management Program • 3
Figure 1: Eagle 2 Data Management Installation Program
5. Follow the on-screen instructions in the InstallShield Wizard
Window to install the program.
6. If the InstallShield Wizard finds versions of Windows® files
on your computer newer than those in the product CD or
installation CD, it will ask you if you want to keep these
newer files. Click Yes.
7. When the InstallShield Wizard indicates that installation is
complete, click the Finish button.
8. Eject the CD from the CD-ROM drive and store it in a safe
place.
4 • Installing the Eagle 2 Data Logger Management Program
IrDA Downloading Cable
The Eagle 2 communicates with a computer via an on-board
infrared communication port that complies with IrDA protocol
standards.
NOTE: If your computer has a built-in infrared port, you do not
need an adapter cable to download data.
If your computer does not have an infrared port, you will need to
install an IrDA/USB adapter cable on your computer to use the
Eagle 2 Data Logger Management Program with your
Eagle 2. The IrDA/USB cable is available from RKI Instruments,
Inc. See the Spare Parts List at the end of this manual for the
RKI part number. This cable can also be found on many
electronic supply websites.
Some versions of Windows® already have several infrared
device drivers loaded in Windows® and will automatically
recognize a cable during the installation process and guide you
in installing the drivers. Other versions of Windows® will require
you to load device drivers provided by the manufacturer of the
cable during the installation process. RKI makes no warranty for
the operation or compatibility of the drivers with any particular
device.
Installing an IrDA Adapter Cable
After installing the Eagle 2 Data Logger Management Program,
connect the IrDA/USB cable to your computer and follow the
manufacturer’s instructions for installing the cable on your
computer. Make sure the cable is compatible with your
Windows® operating system.
If you do not have instructions from the cable manufacturer for
installing your cable, see your Windows documentation. In
general, you must go to the Control Panel and use the Add
Hardware Wizard to install the cable drivers.
IrDA Downloading Cable • 5
Windows® Wireless Link Operation Note
When using an IrDA adapter cable and the Eagle 2 Data Logger
Management Program on a Windows® computer, it is necessary
to make a special setting in the Wireless Link Configuration
window for proper communication between the Eagle 2 and the
Eagle 2 Data Logger Management Program. This must be done
before attempting to use the program. Follow these steps to
make this setting:
1. Click Start on the Windows® Icon Tray.
2. If Control Panel is available to select in the Start menu,
select it. The Control Panel will appear.
If Control Panel is not selectable in the Start menu but
Settings is, select Settings, then select Control Panel. The
Control Panel will appear.
3. Double click on Wireless Link. The Wireless Link
Configuration Window will appear.
4. Click on the Image Transfer tab.
5. Deselect the selection box for “Use Wireless Link to transfer
images from a digital camera to your computer.”
6 • IrDA Downloading Cable
Deselect
Figure 2: Image Transfer Tab
6. Click OK.
7. Close the Control Panel window.
IrDA Downloading Cable • 7
Launching the Program
1. Click Start on the Windows® Icon Tray, then select All
Programs, then select Eagle 2. Your operating system may
also have a shortcut installed in the Start menu.
2. The program will launch and the Download Window will
appear.
Figure 3: The Download Window
3. For convenience, make a shortcut of the Eagle 2 Data
Logger Management Program and place it on the Windows®
desktop. See your Windows® documentation for information
about making shortcuts.
8 • Launching the Program
Control Buttons
This section provides an overview of the control buttons.
Instructions for using the various parts of the program accessed
by the control buttons are given in other parts of this manual.
When the program is launched, it opens in the Download
Window. Along the right side of the Download Window are six
control buttons that access other windows in the program.The
figure below shows the various windows that you can access
when you click the control buttons.
Figure 4: Windows Accessed by Control Buttons
Control Buttons • 9
Download Button
If you are in another program window, clicking the Download
button opens the Download Window (see Figure 3). The
Download window has several download commands that allow
you to perform various data retrieval functions with an
instrument that is connected to the program. Data can be
retrieved from the instrument, data can be cleared from the
instrument, and the instrument can be turned off. See
“Downloading Data from the Eagle 2” on page 15 for a complete
description of downloading data from an Eagle 2.
Instrument Information Button
Clicking the Instrument Information button opens the
Instrument Information Window.
Figure 5: Instrument Information Window
The Instrument Information Window displays various instrument
parameters for an instrument that has been downloaded using
the Complete Download or Instrument Information download
10 • Control Buttons
commands and is currently connected to the program. If an
instrument is turned off after being connected to the program,
then the program will lose the connection with the instrument
and the fields in the Instrument Information Window will become
empty.
Data Button
Clicking the Data button opens the Data Window.
Figure 6: Data Window
In the Data Window, you can view, print, export, and delete data
that has been downloaded from instruments. The following
types of data files are saved in the Data window:
• Calibration History Files
A calibration history file is saved for each instrument that has
been downloaded. It records the calibration information for
every calibration that was downloaded. The Eagle 2 can save
information for up to 100 calibrations in its memory.
Control Buttons • 11
• Interval Trend Data Files
Interval trend data is logged at the interval time defined in the
Eagle 2. Each logged point is an average reading over the
previous time interval.
• Alarm Trend Data Files
Alarm trend data is logged around an alarm event. The Eagle
2 can save up to 8 alarm trend data files in its memory.
• Alarm Event Files
Alarm event files record gas alarm events that have been
downloaded from instruments. The Eagle 2 can save up to
100 alarm events in its memory.
• Trouble Event Files
Trouble event files record sensor failure and system failure
events that have been downloaded from instruments. The
Eagle 2 can save up to 100 trouble events in its memory.
12 • Control Buttons
Last Calibration Button
Clicking the Last Calibration button opens the Last Calibration
Window.
Figure 7: Last Calibration Window
The Last Calibration Window stores the information for the most
recent successful calibration for each Eagle 2 that has been
downloaded. You can display the information three ways by
using the Need Calibration, Calibration Date, or Calibration
Record selection buttons. You can also print the information if
you select the Need Calibration or Calibration Date display
options.
Control Buttons • 13
Set Button
Clicking the Set button opens the Set Window.
Figure 8: Set Window
In the Set Window, you can perform the following functions:
• Alter the appearance of the software windows with the Font
and Color buttons
• Change parameters of a connected instrument by editing the
fields in the Eagle 2 Status frame and in the Gas/Sensor
frame at the bottom of the window and clicking the Update
button
• Update the date and time in a connected instrument by using
the Date/Time Set button
• Calibrate a connected instrument by using the Calibration
button
14 • Control Buttons
Downloading Data from the
Eagle 2
You have the option of downloading data manually or
automatically. If you want to download data using the automatic
download feature, click the Automatic Download selection box in
the Download Window before attempting to download data from
the Eagle 2. Remember that if Automatic Download is selected,
the Instrument Information Window will remain blank and the
Eagle 2 will turn off automatically after the data has been
downloaded. If you want the data in the Eagle 2 to be cleared
automatically after an automatic download, select the Automatic
Data Removal box. The Automatic Data Removal box is only
available for selection if the Automatic Download box is
selected.
Click here for
automatic
downloads
Figure 9: Automatic Download Selection Box
To download data from an Eagle 2:
1. Launch the Eagle 2 Data Logger Management Program. The
Download Window displays. When the program comes up
and no instrument is connected, the Download Commands
are not selectable.
2. Place the Eagle 2 within an inch or two of the infrared port on
your computer aligning the infrared port on the front of the
Eagle 2 with the infrared port on your computer.
If your computer does not have a built in infrared port, place
the Eagle 2 within an inch or two of the infrared port on the
Downloading Data from the Eagle 2 • 15
IrDA adapter cable as shown in Figure 10 below, aligning the
infrared port on the front of the Eagle 2 with the infrared port
on the cable.
Figure 10: Aligning the Eagle 2 with the Cable Infrared Receiver
3. Press and hold the POWER
ENTER RESET button on the
Eagle 2 until you hear a beep,
then release it. The Eagle 2 will
begin its power up sequence. If
a successful connection
between the Eagle 2 and the
Figure 11: Connection
computer occurs, the Connect
Message
light in the Download window
turns green after a few
seconds and “Connection Successful.” displays in the
Download area of the Download window. The Windows®
icon tray will indicate that a wireless connection is in effect.
4. If you selected Automatic Download, the downloading
process begins automatically after a successful connection
is made.
If Automatic Download is not selected, the Complete
Download, Instrument Information, Clear Logger Data, and
16 • Downloading Data from the Eagle 2
Power Off Download Commands become selectable.
5. If you are going to
download data manually,
you can perform a
complete download,
download only the
instrument information, or
download only the data
files by using the Download
Commands.
• To download all data and
instrument information
from the instrument, click
Complete Download.
Figure 12: Download
Commands
• To download instrument
information only, click Instrument Information.
• To download all data, click Download Logger Data.
Download Logger Data becomes selectable only after a
Complete Download or Instrument Information Download
Command has been performed.
6. While the data is being downloaded, messages in the
download message area of the Download window indicate
what actions the program is performing and if there are any
communication or downloading problems. These messages
also tell you what type of information has been downloaded.
Downloading Data from the Eagle 2 • 17
Use to download all data
Use to
download
subsets of
the data
Clear data
button
Download
messages
Instrument
ID
Use to turn
off Eagle 2
Figure 13: Download Messages & Download Commands
7. If the unit has been downloaded manually (Automatic
Download not selected), the unit’s instrument information
may be viewed after downloading by using the Instrument
Information control button if the unit is still turned on and
connected to the computer. For more information on the
Instrument Information screen, see “Viewing Data in the
Instrument Information Screen” on page 22.
18 • Downloading Data from the Eagle 2
Figure 14: Instrument Information Window
8. You can view, print, export, or delete downloaded data by
entering the Data or Last Calibration Windows. These
windows are accessed by clicking Data or Last Calibration
along the right side of the Download Window. See “Viewing,
Printing, Exporting, and Deleting Data in the Data Window”
on page 24 or “Viewing, Printing, and Deleting Data in the
Last Calibration Window” on page 66.
9. After downloading data from an instrument, you can delete
all the data in the Eagle 2 by clicking Clear Logger Data if
desired. This will not delete instrument parameters such as
serial number, alarm settings, or autocalibration settings.
Downloading Data from the Eagle 2 • 19
WARNING: If you click Clear Logger Data, all data is erased
in the Eagle 2, but not in your computer’s
memory. So it’s advisable that you download
the data from the Eagle 2 first before clearing
the data.
Eagle 2 Data Logging Capacity
Table 1: Data Logging Capacity, 4-gas Eagle 2
Interval Trend Time
Data Logging Hours
5 seconds
239 hours (10 days)
10 seconds
479 hours (20 days)
20 seconds
959 hours (40 days)
30 seconds
1439 hours (60 days)
60 seconds
2879 hours (120 days)
180 seconds (3 minutes)
8639 hours (360 days)
300 seconds (5 minutes)
14,399 hours (600 days)
600 seconds (10 minutes)
28,798 hours (2,000 days)
Table 1 above lists the Eagle 2’s data logging capacity for a 4gas unit for each interval trend time setting assuming no alarms
or other events. The interval trend time setting can be set using
the Set Window (see “Changing Eagle 2 Instrument
Parameters” on page 77). It can also be set in the Eagle 2 Setup
Mode (see the Eagle 2 Operator’s Manual).
20 • Eagle 2 Data Logging Capacity
Overwriting Data in the Eagle 2
The Eagle 2’s Data Log Overwrite function is factory set to On
so that when the Eagle 2’s data logging memory becomes full, it
begins to overwrite the oldest interval trend data with new
internal trend data. Download data regularly to avoid overwriting data in the Eagle 2 before it can be downloaded. The
Data Log Overwrite function is accessible using the Eagle 2
Setup Mode. To set the Data Log Overwrite function to Off, see
the Eagle 2 Operator’s Manual. When the Data Log Overwrite
function is set to off, the Eagle 2 will stop saving data when its
data logging memory is full.
The Data Log Overwrite function applies only to interval trend
data. All other data, such as alarm trend data, event data, or
calibration data, will continue to be saved when the memory is
full. If the maximum number of each of these types of data has
been reached, the oldest data will be overwritten.
Overwriting Data in the Eagle 2 • 21
Viewing Data in the Instrument
Information Screen
You can view information for an instrument that has been
downloaded and is currently connected by using the Instrument
Information Window. Information cannot be printed or deleted in
this window. Once the instrument is turned off, the Instrument
Information Window becomes blank. Access the Instrument
Information Window by clicking the Instrument Information
button along the right side of the program window. The
Instrument Information Window will display.
Figure 15: Instrument Information Window
• The serial number, station ID, and user ID are displayed in
the upper left portion of the Instrument Information Window.
• The Calibration History Frame is displayed in the upper right
section of the window and it shows the information for the
most recent successful calibration of the connected
instrument.
22 • Viewing Data in the Instrument Information Screen
• Gas - Lists each channel’s gas in the order it appears on
the Eagle 2 screen.
• Calib. Date - Shows the date and time of the most recent
successful calibration for each channel.
• Before — shows the gas response prior to calibration.
• After — shows the gas response after calibration.
• A. Cal. — lists the auto-calibration setting for each channel
of the Eagle 2. If a Eagle 2 passes its calibration, the
“After” column should match the “A. Cal.” column. If the
Eagle 2 fails calibration on any of its channels, those
channels will retain the previous calibration information.
NOTE: If a unit is calibrated using Single Calibration in the
Eagle 2’s Calibration Mode (see the Eagle 2 Operator’s
Manual) it is possible for the “After” reading to be
different from the “A.Cal” setting if the unit was set to a
level different than the “A.Cal” setting.
• Cal. Due (Days) - Shows how many days remain before
calibration is required for each gas.
• The Warning and Alarm Point Frame is displayed in the lower
half of the window.
• Gas - Lists each channel’s gas in the order it appears on
the Eagle 2 screen.
• Warning - Shows the warning setpoint.
• Alarm - Shows the alarm setpoint.
• STEL - Shows the STEL (short term exposure limit)
setpoint for applicable gases.
• TWA - Shows the TWA (time-weighted average) setpoint
for applicable gases.
All values in the Warning and Alarm Point Frame can be
changed using the Set window.
Viewing Data in the Instrument Information Screen • 23
Viewing, Printing, Exporting, and
Deleting Data in the Data Window
The Eagle 2 logs four types of data files: calibration history,
interval trend data, alarm trend data, and event data.
You can view, print, and export (save to a file) each of these
types of data files. All of these types of data files can also be
deleted. The deleting of files is password protected and is
described in “Deleting Data in the Data Window” on page 60.
Data Window
All the data, other than the most recent calibration information
accessible in the Last Calibration Window, can be accessed in
the Data Window. The Data Window is accessed by clicking
Data along the right side of the program window.
Double-click to
show data
folders
Click to
expand
folder
Click to show
interval trend
files
Interval trend
files
Figure 16: Data Window, Basic Data Organization
24 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
The Data Window is divided into four frames. The upper left
frame is the Data Frame and displays all the data folders. They
are grouped under the Eagle 2 icon in the upper left part of the
frame. If the data folders are not visible, double click the
Eagle 2 icon to make them visible. If no data has been saved,
then no folders will appear when the Eagle 2 icon is double
clicked.
The lower left frame contains three selection boxes for
organizing data. If none of the boxes are selected, then the data
is organized as shown in Figure 16. The data may be organized
by one or more of the following parameters: serial number,
station ID, or user ID. Click the selection box or boxes in the
lower left frame to organize the data as desired.
NOTE: In the examples that follow, the data will be shown
organized by serial number. If you do not select any of
the organization boxes or select the Station ID or User
ID boxes instead of or in addition to the Serial No. box,
your Data Window will look slightly different. The
following examples also show the combustible channel
as “CH4”. The catalytic combustible channel may be
configured for a different gas. See the Eagle 2
Operator’s Manual for details regarding the
configuration of the catalytic combustible channel.
The upper right frame shows the contents of a data folder that is
selected in the Data Frame. The lower right frame shows the
summary information for a data file that is selected in the upper
right frame.
The View Data control button is located at the bottom of the
lower right frame. The View Data button becomes active when a
data file is selected in the upper right frame. Clicking View Data
opens the data file and displays the data.
NOTE: If data is being viewed and the data folders are left open
before instrument downloading is done, close all folders
after downloading and re-open them to be able to view
newly downloaded files.
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 25
Calibration History
The Eagle 2 is capable of saving calibration information for up to
the 100 most recent calibrations. This calibration history is
retrieved by the Data Logger Management Program when data
is downloaded from the Eagle 2 using either the Complete
Download download command or the Download Logger Data
download command.
Instrument calibration information is also available in the Last
Calibration Window. The information regarding the most recent
successful calibration for each downloaded instrument along
with whether or not an instrument is due for calibration can be
accessed using the Last Calibration button on the right side of
the program window. See “Viewing, Printing, and Deleting Data
in the Last Calibration Window” on page 66 for a complete
description of the information that can be accessed by the Last
Calibration button.
All downloaded calibration information for all downloaded
instruments is available in the Calibration History folders in the
Data Window. This information is saved in a Calibration History
Folder that is located in an untitled folder for each instrument.
The calibration history files are differentiated by instrument. The
calibration information available here is more comprehensive
than that in the Last Calibration Window. The calibration
information for all calibrations downloaded, whether successful
or not, is saved instead of just the most recent successful
calibration for each instrument.
26 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
To view, print, or export the calibration history for any instrument
in the database:
1. With the software already launched, click the Data control
button along the right side of the program window. The Data
Window will appear.
Double-click to
show data
folders
Click to
expand folder
Click to
show Cal.
Histories File
Cal.
Histories
file
Figure 17: Data Window - Selecting Calibration History Files
2. If necessary, double-click the Eagle 2 icon in the top of the
Data Window’s upper left frame to see the folders of
downloaded data.
3. Find your instrument by serial number, then click the
expanded view symbol (+) of or double-click the serial
number folder to view the contents.The top folder is untitled
and contains the Calibration History Folder along with folders
for alarm events and trouble events. The rest of the folders
contain folders for the interval trend files and alarm trend
files and are named and organized by date (month/year).
4. Click the expanded view symbol (+) of or double-click the
untitled folder. The Calibration History folder will appear
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 27
below the untitled folder along with the Alarm Events and
Trouble Events folders.
5. Click the Calibration History folder. The Calibration Histories
file or files for that instrument will appear in the top right
frame. If multiple Station ID’s or User ID’s are used for an
instrument, then more than one Calibration Histories file will
appear.
6. Click a file to select it. The first two calibrations saved will be
shown in the bottom right frame along with the total number
of calibrations saved if it is more than two.
7. To view the Calibration Histories file in table format, double
click the Calibration Histories file or click the View Data
button. Calibration Histories files can only be viewed in table
format.
Figure 18: Data View, Calibration History
8. If you click the Summary button, the Data Window will split
into two frames one above the other with the calibration
history list in the lower frame and the summary information
shown in the upper frame. The summary information is the
instrument serial number, station ID, user ID, and the last
download date. To return to the one frame format, click
Summary again.
28 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
9. If you want to print the data, click the Print button. A Printer
List dialog box will appear for you to select a printer.
Figure 19: Printer List Dialog Box, Calibration History
10.Select a printer and click OK to print the data.
11.To export the data for use in another application, for example
a spreadsheet or database, click the Export button. A “Save
As” dialog box will appear for you to specify the filename, file
type, and file location. The default file type is “.csv” (commaseparated values).
Figure 20: Save as Dialog Box
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 29
After specifying the file name, file type, and file location click
the Save button to save the file to the specified location.
12.To go back and view other data, click the Return button in
the upper right corner of the Data Window or the Data
control button on the right side of the program window and
select the data you want to view.
Event Data
The Eagle 2 not only saves trend files which include logged data
at scheduled times, but also saves the 100 most recent alarm
events and the 100 most recent trouble events. When an
instrument is downloaded, the Eagle 2 Data Logger
Management Program will retrieve these events from an
instrument and save them in alarm event files and trouble event
files for each instrument that is downloaded.
Alarm event files save the time, instrument channel, gas, and
alarm type of every gas alarm event that occurs on a particular
instrument. Warning (low alarm), Alarm (high alarm), STEL,
TWA, and overscale events are saved.
Trouble event files note the time, instrument channel, whether
the event is an instrument system failure or sensor failure and
the specific type of failure. Calibration failures, dead battery
alarms, and sensor failures are among the trouble events that
are saved.
30 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
To view, print, or export the event data for any instrument in the
database:
1. With the program already launched, click the Data control
button along the right side of the program window. The Data
Window will appear.
Double-click to
show data folders
Click to expand
folder
Click to show
alarm event file
Alarm event
file
Figure 21: Data Window - Selecting Event Data Files
2. If necessary, double-click the Eagle 2 icon in the top of the
Data Window’s upper left frame to see the folders of
downloaded data.
3. Find your instrument by serial number, then click the
expanded view symbol (+) of or double-click the serial
number folder to view the contents.The top folder is untitled
and contains the Alarm Events Folder and Trouble Events
Folder along with the Calibration History Folder. The rest of
the folders contain folders for the interval trend files and
alarm trend files and are named and organized by date
(month/year).
4. Click the expanded view symbol (+) of or double-click the
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 31
untitled folder. The Alarm Events Folder and Trouble Events
Folder will appear below the untitled folder along with the
Calibration History Folder.
5. Click the Alarm Events or Trouble Events folder. One or
more alarm or trouble event files will appear in the top right
frame. An Alarm Events Folder has been opened in the
example in Figure 21. If multiple User IDs or Station IDs are
used for an instrument, then more than one event file will
appear.
6. Click the desired event file to select it. An event list will
appear in the bottom right frame with the date, time, channel,
gas for an alarm file or general failure type for a trouble file,
and specific event type for the first ten events saved in the
selected file. If more than ten events are saved, the first eight
events are shown and the total number of events in the file is
shown at the bottom of the list (see Figure 21).
7. Click the View Data button at the bottom of the Data Window
or double-click the event file name to open the file and view it
in table format. Event files can only be viewed in table
format.
Figure 22: Data View - Alarm Events
32 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
Figure 23: Data View - Trouble Events
8. If you click the Summary button, the Data Window will split
into two frames one above the other with the event list in the
lower frame and the summary information shown in the
upper frame. The summary information is the same as the
information shown in the upper right frame in Figure 21. The
summary information is the instrument serial number, station
ID, user ID, and the last download date. To return to the one
frame format, click Summary again.
9. If you want to print the data, click the Print button. A Printer
List dialog box will appear for you to select a printer.
Figure 24: Printer List Dialog Box, Event Data
10.Select a printer and click OK to print the data.
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 33
11.To export the data for use in another application, for example
a spreadsheet or database, click the Export button. A “Save
As” dialog box will appear for you to specify the filename and
file location. The default file type is “.csv” (comma-separated
values).
Figure 25: Save as Dialog Box
12.After specifying the file name, file location, and file type click
the Save button to save the file to the specified location.
13.To go back and view other data, click the Return button in
the upper right corner of the Data Window or the Data
control button on the right side of the program window and
select the data you want to view.
Interval Trend Data
Average gas concentrations over the user defined interval trend
time are logged in the interval trend data files. The interval trend
time is set using either the Data Log Interval menu item in the
Eagle 2 Setup Mode or the Interval Trend Time item in the Set
window. See “Changing Eagle 2 Instrument Parameters” on
page 77 or the Eagle 2 Operator’s Manual for instructions to set
the interval trend time. Events such as gas alarms or sensor
failures are saved in the interval trend data file when they occur.
34 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
An interval trend data file is created and saved in the Eagle 2
when the instrument is turned off or when a user ID, station ID,
or catalytic combustible channel gas configuration (using the
relative response feature in Display Mode) is changed during
operation. The serial number, user ID, station ID, and catalytic
combustible channel configuration that are entered in the
instrument when it is turned on or that are updated during
operation are saved for the corresponding interval trend file. If
the instrument’s user ID or station ID are changed during
operation, any interval trend files that result from subsequent
operating sessions will have the new user ID or station ID saved
in them. If the catalytic combustible channel gas configuration is
changed during operation using the relative response feature in
Display Mode, the new configuration will be saved in the data
until it is changed or the unit is turned off. Any catalytic
combustible channel gas configuration changes made using the
relative response feature in Display Mode are cleared when the
unit is turned off and the unit returns to its original configuration
when it is turned on.
The data may be viewed either in table format or graph format if
at least 5 scheduled data points have been logged at the
programmed interval trend time. This does not include events. If
an interval data file has fewer than five scheduled data points,
the graph controls are not functional and the data cannot be
graphed.
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 35
To view and perform desired operations with the interval trend
files:
1. With the program already launched, click the Data control
button along the right side of the program window. The Data
Window will appear.
Double-click
to show
data folders
Click to
expand
folder
Click to show
interval trend
files
Interval trend
files
Figure 26: Data Window - Selecting Interval Trend Data Files
2. If necessary, double-click the Eagle 2 icon in the top of the
Data Window’s upper left frame to see the folders of
downloaded data.
3. Find your instrument by serial number, then click the
expanded view symbol (+) of or double-click the serial
number folder to view the contents.The top folder is untitled
and contains the Calibration History, Alarm Event, and
Trouble Event folders. The rest of the folders contain folders
for the interval trend files and alarm trend files and are
named and organized by date (month/year).
4. Click the expanded view symbol (+) of or double-click the
36 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
dated folder whose contents you want to see.
5. Click on the Interval Trend Folder. In the upper right frame of
the Data Window, a list of file names will appear in the Name
column. A prefix of “iv” indicates an interval trend data file.
6. Click one of the interval trend data file names. A summary
will appear in the bottom right frame with instrument and
alarm setting information. If you want to view, graph, print, or
export the interval trend data, double-click the filename or
click the View Data button at the bottom of the window.
7. Interval trend data can be viewed in either table or graph
format by selecting the Table or Graph selection buttons.
The example below in Figure 27 is shown in table format.
Select table or
graph view
Click to see
events only
Click to see
condensed data
Click to print data
Click to save data to a file
Click to show
session summary
Click to return to
Data Window
Figure 27: Interval Trend Data in Table Format
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 37
• In table format, the interval trend data is shown as the
average gas readings over the user defined interval trend
time. So if the data logging session started at 4:13:38 PM
and the interval time is set to 1 minute, then the readings
logged at 4:14:38 PM are the average reading for each
channel over that one minute period.
• Events are displayed on the screen under the channel in
which they occur and with the time of the event. Events
are displayed whether they occurred at scheduled log
times or in between them. Events include gas alarms such
as a warning condition, trouble conditions such as a
sensor failure, and an indication that the unit is returning to
“normal” condition after an alarm has been reset using the
POWER ENTER RESET button on the Eagle 2.
• If you click the Summary button, the Data Window will
split into two frames, one above the other, with the data
table in the lower frame and the summary information
shown in the upper frame. The summary information is the
same as the one shown in the lower right frame in
Figure 26. To return to the one frame format, click
Summary again.
38 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
• The catalytic combustible channel can be recorded in
%LEL, ppm, or %volume units depending on the
instrument setting. When viewing the interval trend data in
table format, the units are displayed as the unit the reading
was recorded in.
Figure 28: Interval Trend Data Table Format (4 Gas)
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 39
• If installed, an infrared methane or hydrocarbon channel
records data in %LEL and/or % volume units depending
on whether the channel is configured as a % LEL channel
or a %LEL/% volume autoranging channel. When viewing
the interval trend data in table format, the units are
displayed as the unit the reading was recorded in. In the
following figure, the first channel is a catalytic LEL channel
and the fifth channel is an IR autoranging CH4 channel.
Figure 29: Interval Trend Data Table Format (Autoranging)
40 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
8. When the data is viewed in table format, if you move the
cursor over an alarm event, it will change into a small symbol
that looks like an alarm trend data file while it is kept over the
alarm event.
Alarm
Trend
Cursor
Symbol
Figure 30: Alarm Trend Cursor Symbol
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 41
If you click on the event, the corresponding alarm trend data
file will be opened in a new window that pops up over the
Data Window. No control buttons will be visible along the
right side of the new window when an alarm trend data file is
displayed in this way. To return to the interval trend data file,
click the Return button or click the “X” in the upper right
corner of the new window to close the window.
Click to return to interval trend data
Figure 31: Data Displayed by Alarm Trend Cursor Symbol
9. To view only events in the interval trend data file, click the
Events Only selection box to select it.
10.To view the interval trend data in condensed form, click the
Condensed selection box to select it. When the data is
condensed, the software shows only important and eventful
data as follows:
• The first and last scheduled data points in the session are
shown.
42 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
• If there are more than two consecutive data points with the
same readings for all channels, only the first and last of
these consecutive data points are shown.
• All events, such as gas alarms or sensor failures, are
shown.
• For any event, the data point before and after the event is
always shown.
11.To view the data in graph format, click the Graph selection
button. Five or more scheduled data points are required in
an interval trend data file to be able to display it in graph
format.
NOTE: The data count shown when you have selected an
interval trend data file, as in Figure 26 above, can be
more than five if you have events, such as the Eagle 2
going into and out of alarm, but you may not have five
scheduled data points.
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 43
Zoom Level
Event Select
Cursor Feature
Catalytic Combustible Channel Reading Units
Figure 32: Interval Trend Data in Graph Format
When viewing interval trend data in graph format, you have
several options:
• You can choose which gas(es) you want to graph by
selecting or deselecting the boxes next to each gas name.
The color of the gas name corresponds with its color on
the graph and on the scale.
• You can choose the zoom level, or displayed time interval,
on the graph. The zoom feature shows greater detail
relative to time. Thus, the length of a time division on the
graph will depend on both the length of the datalogging
44 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
session and on the zoom factor. Depending on the length
of the data session, data sessions that show changing
readings will normally have more choices for zoom levels
than sessions that show stable data to allow for viewing of
gas reading changes in greater detail.
• When selected, the Event feature shows on the graph
where each channel went into and out of alarm and at
what concentration each event occurred.
• When selected, the Cursor feature allows you to display
the gas reading and log time for each data point saved on
the graph. The number of data points on the graph is
minimized depending on the length of a data session by
several means including omitting consecutive data points
that have the same gas readings. As you use the left and
right arrow buttons on your keyboard to move the cursor
across the graph horizontally, readings at specific log
times are displayed. Use the up and down arrows on the
keyboard to move the readings up or down on the screen.
• The catalytic combustible channel can be graphed in
%LEL, ppm, or %volume units. While readings can be
recorded in any of these units and stored in the same file,
those readings may only be graphed in one unit at a time.
If %LEL is chosen as the unit, any ppm or %volume data is
converted and graphed as %LEL. The user may change
back and forth between the units for the graph and still
have all data shown. The CAT Range Select box is where
the user may select %LEL, ppm, or % volume as the units
for the graph. The box just to the right of the selection dots
shows what channel the catalytic combustible detector is
associated with and what color it is displayed in on the
graph. In the example below, the catalytic combustible
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 45
channel is the first channel and is displayed in green.
Zoom Level
Event Select
Cursor Feature
Catalytic Combustible Channel Reading Units
Figure 33: Interval Trend Data in Graph Format
• If installed, an IR HC or CH4 channel can be graphed in
%LEL or % volume in order to accurately depict the full
range of the sensor.
If the channel is configured as a %LEL only channel, then
data will only be recorded in %LEL and the range will be 0100% LEL. Any gas concentration above that level will not
be recorded.
If the channel is configured as a %LEL/% volume
autoranging channel, then data will be recorded in %LEL
and % volume where appropriate. It will record data in
46 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
%LEL up to 100% LEL and then it will start recording data
in % volume up to 100% volume. If %LEL is chosen as the
graphing units, all data collected for a %LEL only channel
will be displayed. Any data collected in an autoranging
configuration that exceeds 100% LEL will not be shown. In
order to view data above 100% LEL, % volume must be
selected. When % volume is selected, all data will be
shown in terms of % volume.
The IR Range Select box located in the bottom right
corner of the screen is where the unit selection is made for
the IR channel. The box next to the selection dots
indicates what channel the IR sensor is associated with
and what color is used to indicate that channel on the
graph. In the example below, the IR channel is the first
channel and its information is displayed in green.
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 47
Zoom Level Catalytic combustible
channel reading units
IR HC or CH4
Cursor feature
autoranging sensor
channel reading units
Event select
Figure 34: Interval Trend Data in Graph Format With Autoranging
NOTE: The IR Range Select selection box in the lower right
hand corner only appears if an IR HC or CH4 sensor is
installed, is in use, and is set up for autoranging. If an IR
HC or CH4 sensor is not installed, if its channel is turned
off, or if the channel is set up for % LEL only, this box
will not appear.
• If you click the Summary button, the data window will split
into two frames one above the other with the graph in the
lower frame and the summary information shown in the
upper frame. The summary information is the same as the
48 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
information shown in the lower right frame in Figure 26. To
return to the one frame format, click Summary again.
12.To print the data, whether it is viewed in table or graph
format, click the Print button. A Printer List dialog box will
appear for you to select a printer.
Figure 35: Printer List Dialog Box, Interval Data
13.Select a printer and click OK to print the data. Data
displayed in Graph view will print as a graph and data
displayed in Table view will print as a table.
14.To export the data to a file so it can be used by another
application, for example a spreadsheet or database (for table
data) or a word processing or presentation program (for
graph data), click the Export button. A “Save As” dialog box
will appear for you to specify the filename, file location, and
file type.
Figure 36: Save as Dialog Box
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 49
For Graph view, the export file type is Windows bitmap
(.bmp). For Table view, the default file type is “.csv” (commaseparated values). After specifying the file name, file
location, and file type, click the Save button to save the file to
the specified location.
15.To go back and view other data, click the Return button in
the upper right corner of the Data Window or the Data
control button on the right side of the program window and
select the data you want to view.
Alarm Trend Data
In addition to the interval trend data, the Eagle 2 also saves files
that describe the most recent gas alarm events. If a gas alarm
event occurs, then an alarm trend file that is centered around
the event is saved separately from the interval trend data files. It
shows the readings up to 30 minutes before and 30 minutes
after the event, with the log interval time every five seconds. The
gas readings logged at the alarm event time are highlighted in
red and the gas readings logged every 5 seconds around the
alarm event are the peak (minimum for oxygen) readings for the
previous five seconds. If the Eagle 2 was operating in Inert
Mode at the time of the alarm, the maximum oxygen readings
will be saved. If the Eagle 2 has not been on for 30 minutes
before the alarm event occurs, the data during this time is left
blank. If the Eagle 2 is turned off less than 30 minutes after an
alarm event occurs, the data file will only have logged data until
the unit was turned off.
The Eagle 2 saves up to 8 alarm trend files. When an alarm
event triggers an alarm trend file to be saved, subsequent alarm
events must occur 15 minutes after the previous triggering event
in order to trigger the saving of another alarm trend file. If 8
alarm trend files are already saved in the Eagle 2’s memory, the
oldest alarm trend file is overwritten when a new alarm trend file
is saved. Alarm trend data can always be displayed in either
table or graph format.
50 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
To view and perform desired operations with the alarm trend
files:
1. With the software already launched, click the Data control
button along the right side of the program window. The Data
Window will appear.
Double-click to
show data folders
Click to expand
folder
Click to show
alarm trend files
Alarm trend files
Figure 37: Data Window - Selecting Alarm Trend Data Files
2. If necessary, double-click the Eagle 2 icon in the top of the
Data window’s upper left frame to see the folders of
downloaded data.
3. Find your instrument by serial number, then click the
expanded view symbol (+) of or double-click the serial
number folder to view the contents.The top folder is untitled
and contains the Calibration History folder along with folders
for alarm events and trouble events. The rest of the folders
contain folders for the interval trend files and alarm trend
files and are named and organized by date (month/year).
4. Click the expanded view symbol (+) of or double-click the
dated folder whose contents you want to see.
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 51
5. Click on the Alarm Trend Folder in the upper left frame. In
the upper right frame of the Data window, a list of file names
will appear in the Name column. A prefix of “al” indicates an
alarm trend data file.
6. Click one of the alarm trend data file names. A summary will
appear in the bottom right frame with instrument and alarm
setting information. If you want to view, graph, print, or export
the alarm trend data, double-click the filename or click the
View Data button at the bottom of the window.
7. Alarm trend data can be viewed in either table or graph
format by selecting the Table or Graph selection buttons.
The example below in Figure 38 is in table format.
Select table or
graph view
Click to print data
Unit Selection Box
Click to save data to a file
Click for a summary
of the data
Alarm Event
Figure 38: Alarm Trend Data in Table Format
52 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
• In table format, the log times are shown along with the
peak (minimum for oxygen) gas readings for the previous
five seconds.
• The gas readings at the time of the alarm event around
which the logged data are centered are highlighted in red
and are the instantaneous readings at that time.
• The catalytic combustible channel can be recorded in
%LEL, ppm, or %volume units depending on the
instrument setting. When viewing the alarm trend data in
table format, the units for the catalytic LEL channel are
shown in %LEL. The displayed units can be changed to
ppm or %volume using the selection box in the bottom left
portion of the screen.
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 53
• If installed, an infrared methane or hydrocarbon channel
records data in %LEL and/or % volume units depending
on whether the channel is configured as a % LEL channel
or a %LEL/% volume autoranging channel. When viewing
the alarm trend data in table format, the units are
displayed as the unit the reading was recorded in. In the
following figure, the first channel is a catalytic LEL channel
and the fifth channel is an IR autoranging CH4 channel.
Catalytic Combustible Channel
IR Autoranging Channel
Catalytic Units Selection Box
Figure 39: Alarm Trend Data in Table Format
• If you click the Summary button, the data window will split
into two frames one above the other with the data table in
the lower frame and the summary information shown in
the upper frame. The summary information is the same as
the information shown in the lower right frame in
Figure 37.
54 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
8. The Event Only and Condensed selection boxes are not
selectable for alarm trend files.
9. To view the data in graph format, click the Graph button. An
alarm trend file can always be graphed regardless of the
number of logged points.
Zoom level
Cursor feature
Catalytic combustible channel reading units
Figure 40: Alarm Trend Data in Graph Format
When viewing alarm trend data in graph format, you have
several options:
• You can choose which gas(es) you want to graph by
selecting or deselecting the boxes next to each gas name.
The color of the gas name corresponds with its color on
the graph and on the scale.
• The catalytic combustible channel can be graphed in
%LEL, ppm, or %volume units. While readings can be
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 55
recorded in any of these units and stored in the same file,
those readings may only be graphed in one unit at a time.
If %LEL is chosen as the unit, any ppm or %volume data is
converted and graphed as %LEL. The user may change
back and forth between the units for the graph and still
have all data shown. The CAT Range Select box is where
the user may select %LEL, ppm, or % volume as the units
for the graph. The box just to the right of the selection dots
shows what channel the catalytic combustible detector is
associated with and what color it is displayed in on the
graph. In the example below, the catalytic combustible
channel is the first channel and is displayed in green.
Zoom level
Cursor feature
Catalytic combustible channel reading units
Figure 41: Alarm Trend Data in Graph Format
• If installed, an IR HC or CH4 channel can be graphed in
%LEL or % volume in order to accurately depict the full
56 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
range of the sensor.
If the channel is configured as a %LEL only channel, then
data will only be recorded in %LEL and the range will be
0-100% LEL. Any gas concentration above that level will
not be recorded.
If the channel is configured as a %LEL/% volume
autoranging channel, then data will be recorded in %LEL
and % volume where appropriate. It will record data in
%LEL up to 100% LEL and then it will start recording data
in % volume up to 100% volume. If %LEL is chosen as the
graphing units, all data collected for a %LEL only channel
will be displayed. Any data collected in an autoranging
configuration that exceeds 100% LEL will not be shown. In
order to view data above 100% LEL, % volume must be
selected. When % volume is selected, all data will be
shown in terms of % vol.
The IR Range Select box located in the bottom right
corner of the screen is where the unit selection is made for
the IR channel. The box next to the selection dots
indicates what channel the IR sensor is associated with
and what color is used to indicate that channel on the
graph. In the example below, the IR channel is the first
channel and its information is displayed in green.
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 57
Zoom level
Cursor feature
Catalytic combustible channel reading units
IR HC or CH4
channel units
Figure 42: Alarm Trend Data in Graph Format
NOTE: The IR Range Select selection box in the lower right
hand corner only appears if an IR HC or CH4 sensor is
installed, is in use, and is set up for autoranging. If an IR
HC or CH4 sensor is not installed, if its channel is turned
off, or if it’s set up for % LEL only, this box will not
appear.
• You can choose the zoom level, or displayed time interval,
on the graph. The zoom feature shows greater detail
relative to time. Thus, the length of a time division on the
graph will depend on both the length of the datalogging
session and on the zoom factor.
58 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
• When selected, the Event feature shows on the graph
where each channel went into and out of alarm and at
what concentration each event occurred.
• When selected, the Cursor feature allows you to display
the gas reading and log time for each data point in the
alarm trend file. As you use the left and right arrow buttons
on your keyboard to move the cursor across the graph
horizontally, readings at specific log times are displayed.
Use the up and down arrows on the keyboard to move the
readings up or down on the screen.
• If you click the Summary button, the data window will split
into two frames one above the other with the graph in the
lower frame and the summary information shown in the
upper frame. The summary information is the same as the
information shown in the lower right frame in Figure 37. To
return to the one frame format, click Summary again.
10.To print the data, whether it is viewed in table or graph
format, click the Print button. A Printer List dialog box will
appear for you to select a printer.
Figure 43: Printer List Dialog Box, Interval Data
11.Select a printer and click OK to print the data. Data
displayed in Graph view will print as a graph and data
displayed in Table view will print as a table.
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 59
12.To export the data for use in another application, for example
a spreadsheet or database (for table data) or a word
processing or presentation program (for graph data), click
the Export button. A “Save As” dialog box will appear for you
to specify the filename, file location, and file type.
Figure 44: Save as Dialog Box
For Graph view, the export file type is Windows bitmap
(.bmp). For Table view, the default file type is “.csv” (commaseparated values). After specifying the file name, file
location, and file type, click the Save button to save the file to
the specified location.
13.To go back and view other data, click the Return button in
the upper right corner of the Data Window or the Data button
on the right side of the program window and select the data
you want to view.
Deleting Data in the Data Window
The following items can be deleted in the Data Window:
• Data folders
• Calibration History files
• Alarm and Trouble Event files
60 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
• Interval Trend and Alarm Trend data files
To delete any of the above items in the Data Window:
1. With the program launched, click the Data control button on
the right side of the program window.
2. Find the folder or file you want to delete.
3. Place the cursor on the folder or file you want to delete and
click it with the right mouse button. The Delete box will
appear.
Figure 45: Delete Box
4. Click Delete with the left mouse button. The Password
Window appears.
Figure 46: Password Window
5. Enter the password and click Continue. The password when
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 61
the program is first installed is “rki”. The password is case
sensitive. See “Changing the Password” on page 63 for
instructions to change the password if desired.
6. When the password has been entered and Continue
clicked, the Delete Data Window (if a folder is selected for
deletion) or Delete Sample Window (if a file is selected for
deletion) will appear asking you to confirm that you want to
delete the selected folder or file. In the example below, the
Delete Data Window appears because the data folder shown
in Figure 45 has been selected for deletion.
Figure 47: Delete Data Window
7. If you want to delete the selected item, click Yes. The item
will be deleted by the program.
If you do not want to delete the selected item, click No and
the operation will be cancelled.
62 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
Changing the Password
CAUTION: Changing the password requires use of the Delete
box. Take care to avoid accidentally deleting data if
you decide to change the password.
It is possible to change that password as follows:
1. Right-click a data folder, data file, or event file. The Delete
box will appear.
Figure 48: Delete Box
2. Click Delete with the left mouse button. The Password
Window appears.
Figure 49: Password Window
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 63
3. Click Change Password. The Password Window asks you
to input the current password.
Figure 50: Inputting Current Password
4. Type the current password, then click Current password.
The Password Window asks you to input the new password.
Figure 51: Inputting New Password
5. Type the new password and click New Password. The
Password Window asks you to input the new password
again to confirm it.
Figure 52: Confirming New Password
6. Type the new password again, then click Confirm New
Password.
64 • Viewing, Printing, Exporting, and Deleting Data in the Data Window
7. Click OK when the program confirms that you have changed
the password.
Figure 53: Confirming New Password
8. Close the Password Window by clicking the red “X” in the
upper right corner of the window.
Viewing, Printing, Exporting, and Deleting Data in the Data Window • 65
Viewing, Printing, and
Deleting Data in the Last
Calibration Window
You can access data on the most recent successful calibration
for each instrument that has been downloaded in the Last
Calibration Window. You can view, print (calibration date view
option only), and delete this data in the Last Calibration Window.
Viewing and Printing Last Calibration Data
Open the Last Calibration Window by clicking Last Calibration
along the right side of the program window. When you open the
Last Calibration Window the first time after launching the
program, it will open with the Need Calibration view option
selected. There are three view options in the Last Calibration
window: Need Calibration, Calibration Date, and Calibration
Record.
Need Calibration Option
Selecting this option shows the last calibration date and the last
download date for the Eagle 2s that are due for calibration.
NOTE: The calibration interval, the number of days after a
calibration that a new calibration is due, is saved in the
Eagle 2. If the calibration interval is changed in the
Eagle 2, the new calibration interval will not be known
by the program until the Eagle 2 is downloaded.
66 • Viewing, Printing, and Deleting Data in the Last Calibration Window
Figure 54: Last Calibration Window: Need Calibration View Option
The Need Calibration view option shows the following fields:
• No. — lists, in numerical order, the sequence of Eagle 2s
whose data have been downloaded to the program. The
most recently downloaded Eagle 2 will be No. 1.
• SerialNo — shows the serial number of the Eagle 2 that
was downloaded.
• UserID — shows the user ID of the Eagle 2 that was
downloaded.
• StationID — shows the station ID of the unit that was
downloaded.
• Ports (1-4) — shows when the unit was calibrated for each
of the channels using the MM/DD/YY format and 24-hour
military standard time. Each port number corresponds with
a channel number in the Eagle 2. Ports 1-4 correspond
with Channels 1-4 displayed from top to bottom on the
Eagle 2 display when in Measuring Mode. For each serial
number, each port has 2 display lines. The first line
displays the target gas and sensor range. The second line
displays the most recent calibration date or the date the
channel is due for calibration.
NOTE: Your Eagle 2 may have more than 4 sensors installed.
Viewing, Printing, and Deleting Data in the Last Calibration Window • 67
• Last Downloaded — shows when the last download took
place for a unit using the MM/DD/YY format and a 12-hour
clock. This parameter is displayed on the second display
line for each unit downloaded.
The Eagle 2s that are due for calibration (in the case of the
Need Calibration view option, that will be all of them), will have
their last calibration date highlighted in red. The Eagle 2s that
have not been downloaded for more than 90 days will have their
last download date highlighted in purple.
To print a list of the instruments shown in the Need Calibration
view option along with their user ID and last calibration date,
click the Print button. A Printer List dialog box will appear.
Figure 55: Printer List Dialog Box, Need Calibration View Option
Select a printer and click the OK button to print the instrument
list.
Calibration Date View Option
Selecting this option shows the last calibration date and the last
download date for all the Eagle 2s that are in the program’s
database. The fields for the Calibration Date view option are the
same as for the Need Calibration view option.
Figure 56: Last Calibration Window: Calibration Date View Option
68 • Viewing, Printing, and Deleting Data in the Last Calibration Window
To print a list of the instruments shown in the Calibration Date
view option along with their user ID and last calibration date,
click the Print button. A Printer List dialog box will appear.
Figure 57: Printer List Dialog Box, Calibration Date View Option
Select a printer and click the OK button to print the instrument
list.
Calibration Record View Option
Selecting the Calibration Record view option shows detailed
calibration information for each Eagle 2’s most recent successful
calibration.
Figure 58: Last Calibration Window: Calibration Record View Option
The fields on this screen include No., SerialNo, UserID, and
StationID just as in the Need Calibration and Calibration Date
screens. The fields also include the following:
• Gas — Lists the target gas for which the Before, After, and
A.Cal readings are displayed.
Viewing, Printing, and Deleting Data in the Last Calibration Window • 69
• Before — shows the settings prior to calibration.
• After — shows the settings after calibration.
• A. Cal. — lists the auto-calibration setting for each channel
of the Eagle 2. If a Eagle 2 passes its calibration, the
“After” column should match the “A. Cal.” column. If the
Eagle 2 fails calibration on any of its channels, those
channels will retain the previous calibration information.
NOTE: If a unit is calibrated using Single Calibration in the
Eagle 2’s Calibration Mode (see the Eagle 2 Operator’s
Manual) it is possible for the “After” reading to be
different from the “A.Cal” setting if the unit was set to a
level different than the “A.Cal” setting.
• Cal. Due (Days) — shows when calibration is due in days
(e.g., “Remaining 25 Day” means that calibration is due in
25 days, and “Now” means that calibration is due
immediately).
It is not possible to print any information when the Calibration
Record view option is selected.
To view and print all past calibrations for an instrument, see
“Calibration History” on page 26.
Deleting Last Calibration Data
To delete an instrument and its calibration data from the Last
Calibration Window:
1. With the program launched, click Last Calibration on the
right side of the program window. The Last Calibration
Window will appear.
2. Select the Need Calibration or Calibration Date option.
3. Click the first row for the instrument whose calibration
information you want to delete to select it. It will be
highlighted to show that it is selected.
70 • Viewing, Printing, and Deleting Data in the Last Calibration Window
4. Click the row with the right mouse button. The Delete box
appears.
Figure 59: Delete Box
5. Click Delete with the left mouse button. The Password
window appears.
Figure 60: Password Window, Deleting Last Calibration Data
6. Enter the password and click the Continue button. The
password when the software is first installed is “rki”. The
password is case sensitive. See “Changing the Password”
on page 63 for instructions to change the password if
desired.
Viewing, Printing, and Deleting Data in the Last Calibration Window • 71
7. When the password has been entered and the Continue
button clicked, the Delete History window will appear asking
you to confirm that you want to delete the most recent
calibration information for the selected instrument.
Figure 61: Delete History Window
8. If you want to delete the calibration information, click Yes.
The information will be deleted by the program.
If you do not want to delete the calibration information, click
No and the operation will be cancelled.
72 • Viewing, Printing, and Deleting Data in the Last Calibration Window
Calibrating an Eagle 2 With
The Eagle 2 Data Logger
Management Program
An Eagle 2 can be calibrated using the Eagle 2 Data Logger
Management Program. The calibration function is available in
the Set window. To perform a calibration you will need a
calibration kit. This section describes calibration using a
calibration kit that includes a demand flow regulator. If a
calibration kit is used that includes a sample bag and a
dispensing valve instead of a demand flow regulator, connect a
sample bag filled with calibration gas to the Eagle 2’s probe tube
when applying gas instead of connecting the demand flow
regulator to the Eagle 2’s probe tube.
To calibrate the Eagle 2, you will need the following items:
• Known calibrating samples of the gases being detected.
The combustible and toxic gas samples should have
concentrations in approximately the middle of the range of
detection. For the standard 4-gases, a 3-gas or 4-gas mix,
depending on your instrument version, is recommended
so that all channels may be calibrated at once.
• If an optional sensor is installed, this sensor will probably
need to be calibrated individually because its target gas is
not included in a 3-gas or 4-gas mix. The available
optional sensors are PID, ESM-01, IR, or TC sensors.
• A demand-flow regulator to provide adequate sample gas
flow.
• Non-absorbent tubing to connect the regulator to the
Eagle 2’s probe tube.
Calibrating an Eagle 2 With The Eagle 2 Data Logger Management Program • 73
CAUTION: Calibration using the Eagle 2 Data Logger
Management Program should be done in a fresh air
environment, an area free of combustible and toxic
gases and of normal oxygen content (20.9%). If
you suspect the area is not a fresh air environment,
apply zero air to the instrument when performing a
zero operation.
To calibrate an Eagle 2, perform the following steps:
1. Install the Eagle 2’s probe on the inlet fitting.
2. Launch the Eagle 2 Data Logger Management Program.
3. If Automatic Download is selected, deselect it. The Eagle 2
will be turned off by the program after an automatic
download, so calibration will not be possible if Automatic
Download is selected.
4. Connect an Eagle 2 to the program. See “Downloading Data
from the Eagle 2” on page 15 and follow instructions 1-3 to
connect an instrument to the program.
5. Once the connection is made, the Complete Download,
Instrument Information, Clear Logger Data, and Power
Off download commands will be selectable. Click the
Instrument Information download command to retrieve the
instrument information from the Eagle 2. If you wish to
download data before calibrating, click Complete Download
instead of Instrument Information.
74 • Calibrating an Eagle 2 With The Eagle 2 Data Logger Management Pro-
6. Click the Set button to display the Set window.
Click to begin calibration of Eagle 2
Figure 62: Set Window
7. Click the Calibration button in the Eagle 2 Status frame. The
Eagle 2’s pump will turn on. The Calibration frame will
replace the Eagle 2 Status frame and the control buttons
along the right side of the window will become inactive.
Calibrating an Eagle 2 With The Eagle 2 Data Logger Management Program • 75
Click boxes to select
channels for calibration
Set Cal values to match
gas cylinder
Figure 63: Set Window With Calibration Frame
8. Use the selection boxes under the Select column to select
the channels you want to calibrate.
9. Click the Zero button. The software will perform a zero
adjustment setting the oxygen channel to 20.9% and all
other channels to 0.
10.If an optional sensor is installed and its target gas is not
included in the 3-gas or 4-gas mix, the span will need to be
adjusted individually.
11.Verify that the value(s) in the Cal. column match the gas
concentration(s) in the calibration cylinder that will be used.
If not, place the cursor in the field that needs to be changed
and update the value.
12.Screw the demand flow regulator onto the calibration
cylinder.
76 • Calibrating an Eagle 2 With The Eagle 2 Data Logger Management Pro-
13.Connect the regulator to the Eagle 2 probe tube using the
sample tubing provided with the calibration kit.
14.Allow the gas to flow for one minute. The current gas
readings will be shown in the Current Reading column.
15.Click the Span button. The program will make the span
adjustments.
16.Disconnect the tubing from the Eagle 2’s probe tube.
17.Remove the regulator from the cylinder.
18.Allow the current readings to return to normal and click the
Exit Calibration button to return to the Eagle 2 Status frame.
The Eagle 2’s pump will turn off.
19.If you wish to use other functions in the software, click one of
the control buttons.
20.If you wish to exit the software, click the Download button to
return to the Download window. Turn off the Eagle 2 by using
the POWER ENTER RESET button on the Eagle 2 or by
clicking the Power Off button and confirming that you want
to turn off the Eagle 2 when the Power Off window appears.
Then click the Exit button to exit the program.
Changing Eagle 2 Instrument Parameters
To make changes to parameters stored in the Eagle 2, use the
Eagle 2’s Data Logger Management Program’s Set Window.
Follow the steps below to make these changes.
1. Launch the Eagle 2 Data Logger Management Program.
2. If the Automatic Download selection box is selected,
deselect it.
3. Connect an Eagle 2 to the program. See “Downloading Data
from the Eagle 2” on page 15, instruction 2 through
instruction 3, to connect an instrument to the program.
4. Once the connection is made, the Complete Download,
Instrument Information, Clear Logger Data, and Power
Changing Eagle 2 Instrument Parameters • 77
Off download commands will be selectable. Click the
Instrument Information download command to retrieve the
instrument information from the Eagle 2. If you wish to
download data before making changes, click Complete
Download instead of Instrument Information.
5. Click the Set button to display the Set Window. Use the
Eagle 2 Status Frame and the Gas/Sensor Frame to change
parameters stored in the Eagle 2.
Click to upload changes to Eagle 2
Figure 64: Set Window
Alarm settings are shown in the Gas/Sensor Frame at the
bottom of the screen. Settings for installed sensors are
shown in black text. Additional alarm settings for the installed
sensors are shown in green text. The oxygen alarm settings
shown in green at the bottom of the Gas/Sensor Frame are
for Inert Mode. Inert Mode must be activated in the Eagle 2
for this alarm setting to appear. Alarm setting changes made
to the Inert Mode oxygen alarms will not affect the Normal
Mode oxygen alarms. The Normal Mode oxygen alarms can
be viewed and edited above the Inert Mode oxygen alarms in
78 • Changing Eagle 2 Instrument Parameters
the standard four gas section.
6. To change the serial number, click the serial number field
and use the backspace key to remove the current entry, then
type the new information. To change the station ID or user
ID, click the drop-down menu and select the desired station
or user ID.
7. To change the datalogging trend interval time, click on the
down arrow in the Interval Trend Time Field and select the
desired interval time in seconds. The available choices are
5, 10, 20, 30, 60, 180, 300, and 600 seconds.
8. To change the channel parameters, click the field you wish to
change (e.g. H2S AutoCal.) to select it, then type the new
information.
9. After you have finished entering new parameters, you must
upload this information to the Eagle 2 by clicking the Update
button, then confirming that you want to update the
information by clicking the Yes button when the Update
window appears.
Figure 65: Update Window
10.To update the Eagle 2’s date and time to match the
computer’s, click the Date/Time Set button and then click
the Yes button when the Update window appears.
11.If you wish to use other functions in the program, click the
appropriate control button along the right side of the program
window.
12.If you wish to exit the software, click the Download control
button to return to the Download Window. Turn off the Eagle
Changing Eagle 2 Instrument Parameters • 79
2 by using the POWER ENTER RESET button on the Eagle
2 or by clicking the Power Off button and confirming that you
want to turn off the Eagle 2 when the Power Off Window
appears. Then click the Exit button to exit the software.
Detail Settings Button
The Detail Settings button allows the user to create or change a
User ID list or Station ID list and upload it to an instrument, view
the pre-defined relative response gases for the catalytic
combustible channel and edit or add user-defined gases, and
view the pre-defined relative response gases for the PID sensor
and to view or define the 1 user-defined relative response gas.
A Select Distributed File button is located in the bottom right
corner of the Detail Settings window. This control button only
becomes active after data has been downloaded to the Data
Logger Management Program. The function controlled by this
button is not needed for normal field use of the program. This
function is for use by field service personnel with a factory
program at their disposal to generate a distributed file.
The detail settings button is located along the left part of the Set
window under the font and graph color buttons. To update any of
the parameters found in the Detail Settings window in an
instrument, you must first connect the instrument to the
program.
1. Launch the Eagle 2 Data Logger Management Program.
2. If the Automatic Download selection box is selected,
deselect it.
3. Connect an instrument to the program. See “Downloading
Data from the Eagle 2” on page 15, instruction 2 through
instruction 3, to connect an instrument to the program.
4. Once the connection is made, the Complete Download,
Instrument Information, and Power Off download
commands will be selectable. Click the Instrument
Information download command to retrieve the instrument
information from the instrument. If you wish to download data
before making changes, click Complete Download instead
80 • Detail Settings Button
of Instrument Information.
5. Click the Set button to display the Set window.
Figure 66: Set Window
Detail Settings Button • 81
Station & User Tab
The Station & User tab displays a list of Station IDs and User
IDs. The first time the Eagle 2 is connected to the Eagle 2 Data
Logger Management Program, this list will be blank. No Station
IDs or User IDs are loaded into the Eagle 2 at the factory. These
are user-defined parameters that may only be configured using
the Eagle 2 Data Logger Management Program. Up to 128
Station IDs and up to 32 User IDs may be defined.
Figure 67: Station & User Tab
82 • Detail Settings Button
CSV Files
To edit the Station ID or User ID list, you will need to import a csv
(comma separated values) file into the program. A Station csv
file and a User csv file are provided with the program. In
addition, you can generate csv files for editing from the program.
1. To create a csv file for editing, click the “Export csv file”
button located to the right of the Station ID list or the User ID
list.
Click to generate User csv file
Click to generate Station csv file
Figure 68: Station csv File Export
Detail Settings Button • 83
2. Navigate to the location you would like to save the csv file,
type in a file name, and click Save.
Figure 69: Station csv File Save As
84 • Detail Settings Button
3. The csv files can be opened, edited, and saved using a word
processing program such as Word, WordPad, or Notepad.
The Station and User csv files consist of the Station or User
ID number and its associated name. Below is an example of
a Station csv file opened in WordPad.
Figure 70: Station csv File
Any existing Station or User IDs will be displayed. Undefined
Station or User IDs will appear as dashes. To edit a Station or
User ID, delete either the existing name or the dashes and
replace them with the desired name. The name may consist of
any letter, number, or character. If desired, you can save
multiple Station and User ID files.
Loading User and Station IDs
To load new User and Station IDs, do the following:
1. With an instrument connected to the program, locate an
existing Station or User csv file or generate a new one for
editing. See the instructions above to generate a csv file.
Detail Settings Button • 85
2. In the Station and User tab, click “Import csv file” for either
the Station ID or User ID and select a csv file.
Click to import User csv file
Click to import Station csv file
Figure 71: Import csv File
86 • Detail Settings Button
3. Select the file you want to import and click Open.
Figure 72: Station csv File Save As
4. Once the Station ID and/or User ID lists have been imported,
click OK to save changes and return to the Set window.
If you do not want to save the changes, click Cancel.
5. The new station and user ID lists will be visible in the Station
ID and User ID selection boxes in the Set window. Use the
drop down menu to select a current station and user ID for
the instrument.
6. To upload the new information from the Data Logger
Management Program to the Eagle 2, click the Update
button in the Set window.
Detail Settings Button • 87
7. Click Yes in the confirmation window that appears.
Figure 73: Update Confirmation Window
Conversion Table Tab
The Conversion Table tab is used to view the pre-defined
relative response gases for the catalytic combustible channel
and to edit or add user-defined gases. The pre-defined gases
can be found in the Pre-Defined Table tab while the user-defined
gases can be found under the User-Defined Table tab.
Figure 74: Conversion Table
88 • Detail Settings Button
There are 8 columns in both the Pre-Defined Table tab and the
User-Defined Table tab:
• No
This column represents the gas number. The gas numbers
are 1-30.
• Name
This is what will appear in the Relative Response list of
gases. The name can be up to 3 characters long and the
characters must be upper case letters or numbers. No
special characters may be used in the Name column.
• Long Name
The Long Name column is used to better describe the target
gas. It may contain any character in upper- or lower-case.
• Factor
This value is the response factor for the listed gas relative to
methane. The factor for each pre-defined gas is factory
defined. The factor for any user-defined gases must be
obtained through testing as described in “Obtaining a
Relative Response Factor” on page 101. Even if not all of the
user-defined catalytic combustible channels are being
defined, the Factor column must have a valid number
entered. A valid number for the Factor is a value between
0.01 and 25.00.
• 1st
This column is for the low alarm point of each gas in ppm
units.
• 2nd
This column is for the high alarm point of each gas in ppm
units.
• Ratio
The ratio is the ppm value of the LEL for each gas. This value
is specific to each gas and can be easily determined. The
maximum value it may be set to is 150,000 ppm. If an invalid
number is entered, the box will turn red when the csv file is
imported back into the Data Logger Management Program.
Detail Settings Button • 89
NOTE: If you define a gas whose LEL is above 50,000 ppm, the
%LEL reading in Measuring Mode will reflect the
defined ppm ratio, but the ppm reading in Measuring
Mode will not indicate above 50,000 ppm. For example,
if you set the ratio to be 150,000 ppm and set the
catalytic combustible channel to display the reading in
ppm, the gas reading will not indicate higher than
50,000 ppm, the equivalent of 33 %LEL and 5% volume
for this ratio, but will continue to indicate %LEL readings
up to 100 %LEL and %volume readings up to 15
%volume, the equivalent of 150,000 ppm, if the display
units are changed to %LEL or %volume. In addition, all
adjustable ppm parameters cannot be set higher than
50,000 ppm.
• Volt
This value determines the sensor voltage for the catalytic
combustible sensor. It can be set to 1.3 or 2.4. When set to
1.3, the sensor is in methane elimination mode. When set to
2.4, the sensor is reading at full response. Even if not all of
the user-defined catalytic combustible channels are being
defined, the Volt column must have a valid number entered. A
valid number for the Volt column is either 1.3 or 2.4.
90 • Detail Settings Button
While the pre-defined gases may not be edited, the 5 userdefined gases may be edited by doing the following:
1. With the Data Logger Management Program running, click
the Set button to display the Set window. Click the Detail
Settings button to display the Detail Settings window. Click
on the Conversion Table tab and then click on the UserDefined Table tab.
Figure 75: User-Defined Table
2. If no user-defined gases have been previously defined for
the connected instrument, the columns in User-Defined
Table will be blank. Any previously defined gases will appear.
3. Export the current data by pressing the “Export csv file”
button. Choose the file path you wish to save the file in.
Detail Settings Button • 91
4. Open the csv file using Notepad, Word, or WordPad. The
example below shows a csv file opened in WordPad. The list
of gases are associated with the numbers 1-5.
Figure 76: CSV File
If there were no previously defined gases, the csv file will
appear as the following:
Figure 77: Blank CSV File
5. The values in the csv file are all separated by commas.
These values are in the same order as the columns in the
Data Logger Management Program. The first value is the
gas number, the second is the gas name, etc.
6. Edit the values you wish to change and save and close the
file.
92 • Detail Settings Button
7. Return to the Data Logger Management Program with the
User-Defined Table tab still up and press “Import csv file”.
8. Choose the file you just edited and press “Open”.
9. The values you entered in the csv file will appear in the UserDefined Table.
10.If the program finds anything wrong with the values that
were entered, the box containing those values will turn red.
Make sure that you have entered valid characters for each
field.
11.Click OK to save the changes and return to the Set window.
If you do not want to save the changes, click Cancel.
12.To upload the new information from the Data Logger
Management Program to the Eagle 2, click the Update
button in the Set window.
13.Click Yes in the confirmation window that appears.
Figure 78: Update Confirmation Window
Detail Settings Button • 93
PID Sensor Tab
The PID Sensor tab is used to view the pre-defined relative
response gases and to view or define the 1 user-defined relative
response gas. Every gas has a low and high range which are
displayed in the Low Range tab and High Range tab,
respectively.
Figure 79: PID Sensor
There are 13 columns in both the High and Low Range tabs:
• No
This column represents the gas number. They are numbered
1-17.
• Name
This is what will appear in the Relative Response list of
gases. The name can be up to 3 characters long and the
characters must be upper case letters or numbers. No
special characters may be used in the Name column.
• Long Name
The Long Name column is used to better describe the target
gas. It may contain any character in upper- or lower-case.
94 • Detail Settings Button
• Full Scale
This is the full scale value for the target gas.
• Point
The point value indicates to what decimal place the gas
readings are shown. A value of 1/1 indicates a reading to the
“ones” place while a value of 1/100 indicates a reading to the
“hundredths” place.
• Unit
The unit describes what units the gas reading is provided in.
All units are in ppm. While this parameter may be changed in
the csv file, units of ppm are the only acceptable units and
changing this parameter to %LEL or %vol will change the unit
box to red.
• Digit
The digit is the increment of the gas readings.
• 1st
This column is for the low alarm point of each gas in ppm
units.
• 2nd
This column is for the high alarm point of each gas in ppm
units.
• STEL
The STEL column displays the STEL values for each gas.
• TWA
The TWA column displays the TWA values for each gas.
• AutoCal
The AutoCal values are those that come up during the auto
calibration procedure. They are default values that may be
changed if the gas concentration in the calibration cylinder is
different.
• Factor
This value is the Relative Response Factor for the PID
channel. The factor for each pre-defined gas is factory
defined. The factor for the user defined gas must be obtained
Detail Settings Button • 95
from Table 5 on page 102 or through testing as described in
“Obtaining a Relative Response Factor” on page 101. A valid
character for the Factor is a value between 0.01 and 25.00.
There are limitations for the full scale and increment values that
depend on the factor for both the high range and the low range.
Table 2 and Table 3 below list these limitations.
Table 2: High Range PID
Factor
Full Scale
(ppm)
Increment
0.25-0.36
1000
1
0.37-0.49
1500
1
0.50-0.61
2000
1
0.62-0.74
2500
1
0.75-0.99
3000
2
1.00-1.24
4000
2
1.25-2.49
5000
2
2.50-3.74
10000
10
3.75-4.99
15000
10
5.00-7.49
20000
10
7.50-9.99
30000
20
10.0012.49
40000
20
12.50
50000
2500
Table 3: Low Range PID
Factor
Full Scale
(ppm)
Increment
0.20-0.29
10.00
0.01
0.30-0.39
15.00
0.01
0.40-0.49
20.00
0.01
96 • Detail Settings Button
Table 3: Low Range PID
Factor
Full Scale
(ppm)
Increment
0.50-0.59
25.00
0.01
0.60-0.79
30.00
0.02
0.80-0.99
40.00
0.02
1.00-1.99
50.00
0.02
2.00-2.99
100.0
0.1
3.00-3.99
150.0
0.1
4.00-5.99
200.0
0.1
6.00-7.99
300.0
0.2
8.00-9.99
400.0
0.2
10.00
500.0
0.2
Detail Settings Button • 97
While the pre-defined gases may not be edited, the 1 userdefined gas may be edited by doing the following:
1. With Data Logger Management Program running, click on
the Set button to display the Set window. Click the Detail
Settings button to display the Detail Settings window. Click
on the PID Sensor tab and then click on the High Range tab.
Figure 80: High Range Tab
2. If no user-defined PID gas has been previously defined for
the connected instrument, the name and long name will both
appear as PID for the High Range and Low Range tabs. The
full scale, digit, and factor values will appear as shown in
Table 4 below. The rest of the fields will contain asterisks
(*****).
Table 4: Default Values for User Defined PID Gas
Full Scale (ppm)
Digit
Factor
High Range
2000
2
1.00
Low Range
50.00
0.02
1.00
98 • Detail Settings Button
3. Export the current data by pressing the “Export csv file”
button. Choose the file path you wish to save the file in.
Figure 81: Save As
4. Open the csv file using Notepad, Word, or WordPad. The
example below shows a csv file opened in WordPad. The
user defined PID gas is number 17.
Figure 82: CSV File
5. The values in the csv file are all separated by commas.
These values are in the same order as the columns in the
Data Logger Management Program. The first value is the
gas number, the second is the gas name, etc.
Detail Settings Button • 99
6. Edit the values you wish to change and save the file.
7. Return to the Data Logger Management Program with the
High Range tab still up and press “Import csv file”.
8. Choose the file you just edited and press “Open”.
9. The values you entered in the csv file will appear in the High
Range tab.
10.If the program finds anything wrong with the values that
were entered, the box containing those values will turn red.
Make sure that you have entered valid characters for each
field.
NOTE: The Name and Long Name for the Low Range and High
Range tabs must agree. If they do not, the program will
keep the Low Range Name and Long Name and
change the High Range to agree with it.
11.Repeat step 1-step 10 for the Low Range tab.
12.Click OK to save the changes and return to the Set window.
If you do not want to save the changes, click Cancel.
13.To upload the new information from the Data Logger
Management Program to the Eagle 2, click the Update
button in the Set window.
14.Click Yes in the confirmation window that appears.
Figure 83: Update Confirmation Window
100 • Detail Settings Button
Obtaining a Relative Response Factor
If the gas that you want to monitor on the catalytic combustible
or PID channel is not included in the catalytic or PID relative
response lists, you may define up to 5 gases for the catalytic
combustible channel using the Conversion Table tab and 1 gas
for the PID channel using the PID Sensor tab. Testing must be
done using the desired target gas in order to obtain the
response factor value for the catalytic combustible channel. To
determine the relative response factor value for the PID
channel, first look in Table 5 for the desired gas. If the desired
gas does not appear in the table, you must obtain the response
factor through the testing procedure described below.
To determine the relative response factor value for the catalytic
or PID channels, do the following:
1. For determining the catalytic combustible channel relative
response factor, calibrate the catalytic combustible channel
to methane. For determining the PID channel relative
response factor, calibrate the PID channel to isobutylene.
2. Obtain a gas sample of known concentration for the target
gas you wish to define. The sample needs to be at least 10%
of the full scale but RKI Instruments, Inc. recommends using
50% of the full scale. If the concentration tested results in an
overscale reading, test a lower concentration.
3. Apply the gas sample to the EAGLE 2 and take note of the
reading. If the gas sample is of 50 %LEL concentration and
the EAGLE 2 display shows a reading of 25 %LEL, then the
factor for that gas is 2. Conversely, if the gas sample is of 50
%LEL concentration and the EAGLE 2 display shows a
reading of 100 %LEL, then the factor for that gas is 0.5. This
conversion factor value is what you will enter in the Factor
column of the gas you are defining.
Table 5 below has 4 columns:
• Gas/VOC-The most common name for the VOC (volatile
organic compound)
• CAS No.-Sometimes it is easier to identify a VOC from the
internationally recognized CAS (Chemical Abstracts Service)
Detail Settings Button • 101
number
• Formula-Molecular formula for each VOC
• Response Factor (RF)-The relative response factor for each
gas. This is the value that is plugged into the Eagle 2
Maintenance Data Loader Program.
Some abbreviations that appear in the table are:
• ZR-No response
• NV-Cannot be measured
Table 5: Response Factors Relative to Isobutylene
Gas/ VOC
CAS No.
Formula
Acetaldehyde
75-07-0
C2H4O
Relative
Response
4.9
Acetic Acid
64-17-7
C2H4O2
36
Acetic Anhydride
108-24-7
C4H6O3
4
Acetone
67-64-1
C3H6O
0.7
Acetonitrile
75-05-8
CH3CN
ZR
Acetylene
74-86-2
C2H2
ZR
Acrolein
107-02-8
C3H4O
4
Acrylic Acid
79-10-7
C3H4O2
2.7
Acrylonitrile
107-13-1
C3H3N
ZR
Allyl alcohol
107-18-6
C3H6O
2.1
Allyl chloride
107-05-1
C3H5Cl
4.5
Ammonia
7664-41-7
NH3
8.5
Amyl acetate, n-
628-63-7
C7H14O2
1.8
Amyl alcohol
71-41-0
C5H12O
3.2
Aniline
62-53-3
C6H7N
0.5
Anisole
100-66-3
C7H8O
0.5
Arsine
7784-42-1
AsH3
2.5
Asphalt, petroleum fumes
8052-42-4
Benzaldehyde
100-52-7
C7H6O
0.9
1
Benzene
71-43-2
C6H6
0.5
Benzenethiol
108-98-5
C6H5SH
0.7
Benzonitrile
100-47-0
C7H5N
0.7
Benzyl alcohol
100-51-6
C7H8O
1.3
Benzyl chloride
100-44-7
C7H7Cl
0.6
Benzyl formate
104-57-4
C8H8O2
0.8
102 • Detail Settings Button
Gas/ VOC
Biphenyl
CAS No.
Formula
Relative
Response
0.4
92-52-4
C12H10
7/5/38
C6H10O3
3
Boron trifluoride
7637 07 2
BF3
ZR
Bromine
7726-95-6
Br2
20
Bromine pentafluoride
7789-30-2
BrF5
ZR
Bromobenzene
108-86-1
C6H5Br
0.7
Bromochloromethane
74-97-5
CH2ClBr
ZR
Bis(2,3-epoxypropyl) ether
Bromoethane
74-96-4
C2H5Br
5
6482-24-2
C3H7OBr
2.5
Bromoform
75-25-2
CHBr3
2.8
Bromopropane, 1-
106-94-5
C3H7Br
1.3
Bromotrifluoromethane
75-63-8
CF3Br
ZR
0.8
Bromoethyl methyl ether, 2-
Butadiene
106-99-0
C4H6
Butadiene diepoxide, 1,3-
1464-53-5
C4H6O2
4
Butane, n-
106-97-8
C4H10
46
Butanol, 1-
71-36-3
C4H10O
4
Buten-3-ol, 1-
598-32-3
C4H8O
1.2
Butene, 1-
106-98-9
C4H8
1.3
Butoxyethanol, 2-
111-76-2
C6H14O2
1.1
Butyl acetate, n-
123-86-4
C6H12O2
2.4
Butyl acrylate, n-
141-32-2
C7H12O2
1.5
Butyl lactate
138-22-7
C7H14O3
2.5
Butyl mercaptan
109-79-5
C4H10S
0.5
Butylamine, 2-
513-49-5
C4H11N
0.9
Butylamine, n-
109-73-9
C4H11N
1
Camphene
565-00-4
C10H16
0.5
Carbon dioxide
124-38-9
CO2
ZR
Carbon disulfide
75-15-0
CS2
1.4
Carbon monoxide
630-08-0
CO
ZR
Carbon tetrabromide
558-13-4
CBr4
3
Carbon tetrachloride
56-23-5
CCl4
ZR
Carbonyl sulphide
463-58-1
COS
ZR
Carvone, R-
6485-40-1
C10H14O
1
Chlorine
7782-50-5
Cl2
ZR
10049-04-4
ClO2
1
Chlorine dioxide
Chlorine trifluoride
7790-91-2
Chloro-1,1,1,22837-89-0
tetrafluoroethane
Chloro-1,1,1-trifluoroethane, 2- 75-88-7
ClF3
ZR
C2HClF4
ZR
C2H2ClF3
ZR
Chloro-1,1,2,2354-25-6
tetrafluoroethane
Chloro-1,1,2-trifluoroethane, 1- 421-04-5
C2HClF4
ZR
C2H2ClF3
ZR
Chloro-1,1-difluoroethane, 1-
75-68-3
C2H3ClF2
ZR
Chloro-1,1-difluoroethane, 1-
75-68-3
C2H3ClF2
ZR
Chloro-1,1-difluoroethane, 2-
338-65-8
C2H3ClF2
ZR
Chloro-1,2,2-trifluoroethane
431-07-2
C2H2ClF3
ZR
Detail Settings Button • 103
Gas/ VOC
CAS No.
Formula
Chloro-1,3-butadiene, 2-
126-99-8
C4H5Cl
Relative
Response
3.2
Chloro-1-fluoroethane, 1-
1615-75-4
C2H4ClF
ZR
Chloro-2-fluoroethane, 1-
762-50-5
C2H4ClF
ZR
Chloroacetaldehyde
107-20-0
C2H3OCl
ZR
Chlorobenzene
108-90-7
C6H5Cl
0.5
Chlorodifluoromethane
75-45-6
CHClF2
ZR
Chloroethane
75-00-3
C2H5Cl
ZR
Chloroethanol 2-
107-07-3
C2H5ClO
10
Chloroethyl methyl ether, 2-
627-42-9
C3H7ClO
2.6
Chlorofluoromethane
593-70-4
CH2ClF
ZR
Chloroform
67-66-3
CHCl3
ZR
Chloromethane
74-87-3
CH3Cl
ZR
Chloropentafluoroethane
76-15-3
C2ClF5
ZR
Chlorotoluene, o-
95-49-8
C7H7Cl
0.5
Chlorotoluene, p-
108-41-8
C7H7Cl
0.5
Chlorotrifluoroethylene
79-38-9
C2ClF3
1
Chlorotrifluoromethane
75-72-9
CClF3
ZR
Citral
5392-40-5
C10H16O
1
Citronellol
26489-01-0
C10H20O
1
Cresol, m-
108-39-4
C7H8O
1.1
Cresol, o-
95-48-7
C7H8O
1.1
1.1
Cresol, p-
106-44-5
C7H8O
Crotonaldehyde
4170-30-3
C4H6O
1
Cumene
98-82-8
C9H12
0.6
Cyanamide
420-04-2
CH2N2
ZR
Cyanogen bromide
506-68-3
CNBr
ZR
Cyanogen chloride
506-77-4
CNCl
ZR
Cyclohexane
110-82-7
C6H12
1.3
Cyclohexanol
108-93-0
C6H12O
2.9
Cyclohexanone
108-94-1
C6H10O
1.1
Cyclohexene
110-83-8
C6H10
0.8
Cyclohexylamine
108-91-8
C6H13N
1
Cyclopentane
287-92-3
C5H10
4
Decane, n-
124-18-5
C10H22
1
Diacetone alcohol
123-42-2
C6H12O2
0.8
Dibenzoyl peroxide
94-36-0
C14H10O4
0.8
19287-45-7
B2H6
ZR
Dibromochloromethane
124-48-1
CHBr2Cl
10
Dibromodifluoromethane
75-61-6
CF2Br2
ZR
Dibromoethane 1,2-
106-93-4
C2H4Br2
2
Dibromotetrafluoroethane ,
1,2Dibutyl hydrogen phosphate
124-73-2
C2F4Br2
ZR
107-66-4
HC8H18
PO4
C2HCl2F3
4
Diborane
Dichloro-1,1,1-trifluoroethane,
2,2-
104 • Detail Settings Button
306-83-2
ZR
Gas/ VOC
CAS No.
Formula
Dichloro-1,1-difluoroethane,
1,2Dichloro-1,2,2-trifluoroethane,
1,2Dichloro-1,2-difluoroethane,
1,2Dichloro-1-fluoroethane, 1,1-
1649-08-7
Relative
Response
C2H2Cl2F2
ZR
354-23-4
C2HCl2F3
ZR
631-06-1
C2H2Cl2F2
ZR
1717-00-6
C2H3Cl2F
ZR
Dichloro-1-fluoroethane, 1,1-
1717-00-6
C2H3Cl2F
ZR
Dichloro-1-fluoroethane, 1,2-
430-57-9
C2H3Cl2F
ZR
Dichloro-1-propene, 2,3-
78-88-6
C3H4Cl2
1.4
Dichloro-2,2,-difluoroethane,
1,1Dichloroacetylene
79-35-6
C2H2Cl2F2
ZR
7572-29-4
C2Cl2
5
Dichlorobenzene o-
95-50-1
C6H4Cl2
0.5
Dichlorodifluoromethane
75-71-8
CCl2F2
ZR
Dichloroethane 1,2-
107-06-2
C2H4Cl2
ZR
Dichloroethane, 1,1-
75-34-3
C2H4Cl2
ZR
Dichloroethene, 1,1-
75-35-4
C2H2Cl2
1
Dichloroethene, cis-1,2-
156-59-2
C2H2Cl2
0.8
Dichloroethene, trans-1,2-
540-59-0
C2H2Cl2
0.7
Dichloroethylene 1,2-
540-59-0
C2H2Cl2
0.8
Dichlorofluoromethane
75-43-4
CHFCl2
ZR
Dichloromethane
75-09-2
CH2Cl2
39
Dichloropropane, 1,2-
78-87-5
C3H6Cl2
ZR
Dichlorotetrafluoroethane, 1,1-
374-07-2
C2Cl2F4
ZR
Dichlorotetrafluoroethane, 1,2-
76-14-2
C2Cl2F4
ZR
77-73-6
C10H12
Dicyclopentadiene
Diesel Fuel
0.9
68334-30-5
Diethyl ether
60-29-7
Diethyl maleate
Diethyl phthalate
Diethyl sulphate
0.8
C4H10O
0.9
141-05-9
C8H12O4
2
84-66-2
C12H14O4
1
64-67-5
C4H10SO4
3
Diethyl sulphide
352-93-2
C4H10S
0.6
Diethylamine
109-89-7
C4H11N
1
Diethylaminoethanol, 2-
100-37-8
C6H15ON
2.7
Diethylaminopropylamine, 3-
104-78-9
C7H18N2
1
Difluoroethane, 1,1-
75-37-6
C2H4F2
ZR
Difluoroethane, 1,2-
624-72-6
C2H4F2
ZR
Difluoromethane
75-10-5
CH2F2
ZR
Dihydrogen selenide
7783 07 5
H2Se
1
Dihydroxybenzene, 1,2
120-80-9
C6H6O2
1
Dihydroxybenzene, 1,3
108-46-3
C6H6O2
1
Diisobutylene
107-39-1
C8H16
0.6
Diisopropyl ether
108-20-3
C6H14O
0.7
Diisopropylamine
108-18-9
C6H15N
0.7
Diketene
674-82-8
C4H4O2
2.2
Dimethoxymethane
109-87-5
C3H8O2
1.4
Detail Settings Button • 105
Gas/ VOC
CAS No.
Formula
Relative
Response
1.1
Dimethyl cyclohexane, 1,2-
583-57-3
C8H16
Dimethyl disulphide
624-92-0
C2H6S2
0.2
Dimethyl ether
115-10-6
C2H6O
1.3
Dimethyl phthalate
131-11-3
C10H10O4
1
Dimethyl sulphate
77-78-1
C2H6O4S
ZR
Dimethyl sulphide
75-18-3
C2H6S
0.5
Dimethylacetamide N,N-
127-19-5
C4H9NO
1.3
Dimethylamine
124-40-3
C2H7N
1.4
Dimethylaminoethanol
108-01-0
C4H11NO
1.5
Dimethylaniline, NN-
121-69-7
C8H11N
0.6
Dimethylbutyl acetate
108-84-9
C8H16O2
1.6
Dimethylethylamine, NN-
598-56-1
C4H11N
0.8
Dimethylformamide
68-12-2
C3H7NO
0.9
Dimethylheptan-4-one, 2,6-
108-83-8
C9H18O
0.8
Dimethylhydrazine, 1,1-
57-14-7
C2H8N2
1
Dinitrobenzene, m-
99-65-0
C6H4N2O4
3
Dinitrobenzene, o-
528-29-0
C6H4N2O4
ZR
Dinitrobenzene, p-
100-25-4
C6H4N2O4
5
Dinonyl phthalate
84-76-4
C26H42O4
1
C4H8O2
1.5
C4H8O2
1.5
Dioxane 1,2Dioxane 1,4-
123-91-1
Dipentene
138-86-3
C10H16
0.9
Diphenyl ether
101-84-8
C12H10O
0.8
Disulphur decafluoride
5714-22-7
S2F10
ZR
3
Disulphur dichloride
10025-67-9
S2Cl2
Di-tert-butyl-p-cresol
2409-55-4
C11H16O
1
Divinylbenzene
1321-74-0
C10H10
0.4
Dodecanol
112-53-8
C12H26O
0.9
C4H2F5ClO
ZR
Enflurane
13838-16-9
Epichlorohydrin
106-89-8
C3H5ClO
8
Epoxypropyl isopropyl ether,
2,3Ethane
4016-14-2
C6H12O2
1.1
74-84-0
C2H6
ZR
Ethanol
64-17-5
C2H6O
8.7
Ethanolamine
141-43-5
C2H7NO
3
Ethoxy-2-propanol, 1-
1569-02-4
C5H10O2
2
Ethoxyethanol, 2-
110-80-5
C4H10O2
29.8
Ethoxyethyl acetate, 2-
111-15-9
C6H12O3
3
Ethyl (S)-(-)-lactate
97-64-3
C5H10O3
3
Ethyl acetate
141-78-6
C4H8O2
3.6
Ethyl acrylate
140-88-5
C5H8O2
2
Ethyl amine
75-04-7
C2H7N
1
0.5
Ethyl benzene
100-41-4
C8H10
Ethyl butyrate
105-54-4
C6H12O2
1
Ethyl chloroformate
541-41-3
C3H5O2Cl
80
Ethyl cyanoacrylate
7085-85-0
C6H7O2N
1.5
Ethyl decanoate
110-38-3
C12H24O2
1.8
Ethyl formate
109-94-4
C3H6O2
30
106 • Detail Settings Button
Gas/ VOC
CAS No.
Formula
Ethyl hexanoate
123-66-0
C8H16O2
Relative
Response
2.6
Ethyl hexanol, 2-
105-76-7
C8H18O
1.5
Ethyl hexyl acrylate, 2-
103-11-7
C11H20O2
1
Ethyl mercaptan
75-08-1
C2H6S
0.7
Ethyl octanoate
106-32-1
C10H20O2
2.3
Ethylene
74-85-1
C2H4
8
Ethylene dinitrate
628-96-6
C2H4O6N2
ZR
Ethylene glycol
107-21-1
C2H6O2
20
Ethylene oxide
75-21-8
C2H4O
15
Ferrocene
102-54-5
C10H10Fe
0.8
Fluorine
7782-41-4
F2
ZR
Fluoroethane
353-33-6
C2H5F
ZR
Fluoromethane
593-53-3
CH3F
ZR
Formaldehyde
50-00-0
CH2O
ZR
Formamide
75-12-7
CH3ON
2
Formic acid
64-18-6
CH2O2
ZR
Furfural
98-01-1
C5H4O2
1.4
Furfuryl alcohol
98-00-0
C5H6O2
Gasoline vapors
8006-61-9
1.1
Gasoline vapors
8006-61-9
0.8
Gasoline vapors 92 octane
8006-61-9
0.8
Germane
7782-65-2
GeH4
10
Glutaraldehyde
111-30-8
C5H8O2
0.9
Halothane
151-67-7
CF3CHBrCl
ZR
He
ZR
Helium
2
Heptan-2-one
110-43-0
C7H14O
0.7
Heptan-3-one
106-35-4
C7H14O
0.8
Heptane n-
142-82-5
C7H16
2.1
Hexachloroethane
67-72-1
C2Cl6
ZR
Hexafluoroethane
76-16-4
C2F6
ZR
Hexamethyldisilazane,
1,1,1,3,3,3-.
Hexamethyldisiloxane.
999-97-3
C6H19NSi2
1
107-46-0
C6H18OSi2
0.3
Hexan-2-one
591-78-6
C6H12O
0.8
Hexane n-
110-54-3
C6H14
4.2
Hexene, 1-
592-41-6
C6H12
0.9
Hydrazine
302-01-2
H4N2
3
Hydrazoic acid
7782-79-8
HN3
ZR
Hydrogen
1333-74-0
H2
ZR
Hydrogen bromide
10035-10-6
HBr
ZR
Hydrogen chloride
7647-01-0
HCl
ZR
Hydrogen cyanide
74-90-8
HCN
ZR
Hydrogen fluoride
7664-39-3
HF
ZR
Hydrogen peroxide
7722-84-1
H2O2
4
6/4/83
H2S
4
Hydrogen sulfide
Detail Settings Button • 107
Gas/ VOC
CAS No.
Formula
Relative
Response
0.8
Hydroquinone
123-31-9
C6H6O2
Hydroxypropyl acrylate 2-
999-61-1
C6H10O3
1.5
Iminodi(ethylamine) 2,2-
111-40-0
C4H13N3
0.9
Iminodiethanol 2,2'-
111-42-2
C4H11NO2
1.6
Indene
95-13-6
C9H8
0.5
Iodine
7553-56-2
I2
0.2
Iodoform
75-47-8
CHI3
1.5
Iodomethane
74-88-4
CH3I
0.4
Isoamyl acetate
123-92-2
C7H14O2
1.6
Isobutane
75-28-5
C4H10
8
Isobutanol
78-83-1
C4H10O
3.5
Isobutyl acetate
110-19-0
C6H12O2
2.3
Isobutyl acrylate
106-63-8
C7H12O2
1.3
Isobutylene
115-11-7
C4H8
1
Isobutyraldehyde
78-84-2
C4H8O
1.2
Isocyanates, all
Isodecanol
Isoflurane
NV
25339-17-7
C10H22O
26675-46-7 C3H2ClF5O
0.9
ZR
Isononanol
2452-97-9
C9H20O
1.5
Isooctane
565-75-3
C8H18
1.1
Isooctanol
26952-21-6
C8H18O
1.7
Isopentane
78-78-4
C5H12
6
Isophorone
78-59-1
C9H14O
0.8
Isoprene
78-79-5
C5H8
0.7
Isopropanol
67-63-0
C3H8O
4.4
Isopropyl acetate
108-21-4
C5H10O2
2.2
Isopropyl chloroformate
108-23-6
C4H7O2Cl
1.6
Jet Fuel JP-4
0.8
Jet Fuel JP-5
0.7
Jet Fuel JP-8
Kerosene
Ketene
Liquefied petroleum gas
0.7
8008-20-6
463-51-4
0.8
C2H2O
68476-85-7
3
ZR
Maleic anhydride
108-31-6
C4H2O3
2
Mercaptoacetic acid
68-11-1
C2H4O2S
1
7439-97-6
Hg
NV
Mercury
Mercury alkyls
NV
Mesitylene
108-67-8
C9H12
0.3
Methacrylic acid
79-41-4
C4H6O2
2.3
Methacrylonitrile
126-98-7
C4H5N
5
Methane
74-82-8
CH4
ZR
Methanol
67-56-1
CH4O
200
Methoxyethanol, 2-
109-86-4
C3H8O2
2.7
Methoxyethoxyethanol, 2-
111-77-3
C5H12O3
1.4
Methoxymethylethoxy-2propanol
Methoxypropan-2-ol
34590-94-8
C7H16O3
1.3
107-98-2
C4H10O2
3
108 • Detail Settings Button
Gas/ VOC
CAS No.
Formula
Relative
Response
1.2
Methoxypropyl acetate
108-65-6
C6H12O3
Methyl acetate
79-20-9
C3H6O2
5.2
Methyl acrylate
96-33-3
C4H6O2
3.4
1.9
Methyl bromide
74-83-9
CH3Br
Methyl cyanoacrylate
137-05-3
C5H5O2N
5
Methyl ethyl ketone
78-93-3
C4H8O
0.8
Methyl ethyl ketone peroxides
1338-23-4
C8H18O2
0.8
Methyl formate
107-31-3
C2H4O2
ZR
Methyl isobutyl ketone
108-10-1
C6H12O
0.8
Methyl isocyanate
624-83-9
C2H3NO
ZR
Methyl isothiocyanate
556-61-6
C2H3NS
0.6
Methyl mercaptan
74-93-1
CH4S
0.7
Methyl methacrylate
80-62-6
C5H8O2
1.6
Methyl propyl ketone
107-87-9
C5H10O
0.8
Methyl salicylate
119-36-8
C8H8O3
1.2
Methyl sulphide
75-18-3
C2H6S
0.5
1634-04-4
C5H12O
0.8
51-42-8
C4H8O
1.1
0.9
Methyl t-butyl ether
Methyl-2-propen-1-ol, 2Methyl-2-pyrrolidinone, N-
872-50-4
C5H9NO
Methyl-4,6-dinitrophenol, 2-
534-52-1
C7H6N2O5
3
Methyl-5-hepten-2-one, 6-
110-93-0
C8H14O
0.8
Methylamine
74-89-5
CH5N
1.4
Methylbutan-1-ol, 3-
123-51-3
C5H12O
3.4
Methylcyclohexane
108-87-2
C7H14
1.1
2.4
Methylcyclohexanol, 4-
589-91-3
C7H14O
Methylcyclohexanone 2-
583-60-8
C7H12O
1
Methylheptan-3-one, 5-
541-85-5
C8H16O
0.8
Methylhexan-2-one, 5-
110-12-3
C7H14O
0.8
Methylhydrazine
60-34-4
CH6N2
1.3
Methyl-N-2,4, 6tetranitroaniline, NMethylpent-3-en-2-one, 4-
479-45-8
C7H5N5O8
3
141-79-7
C6H10O
0.7
Methylpentan-2-ol, 4-
108-11-2
C6H14O
2.8
Methylpentane-2,4-diol, 2-
107-41-5
C6H14O2
4
Methylpropan-2-ol, 2-
75-65-0
C4H10O
3.5
25013-15-4
C9H10
0.5
Methylstyrene
Mineral oil
Mineral spirits
Naphthalene
8042-47-5
0.8
64475-85-0
0.8
91-20-3
C10H8
10102-43-9
NO
8
Nitroaniline 4-
100-01-6
C6H6N2O2
0.8
Nitrobenzene
98-95-3
C6H5NO2
1.7
Nitroethane
79-24-3
C2H5NO2
ZR
Nitric oxide
0.4
Nitrogen dioxide
10102-44-0
NO2
10
Nitrogen trichloride
10025-85-1
NCl3
1
Nitrogen trifluoride
7783-54-2
NF3
ZR
Nitromethane
75-52-5
CH3NO2
ZR
Nitropropane, 1-
108-03-2
C3H7NO2
ZR
Detail Settings Button • 109
Gas/ VOC
Nitropropane, 2Nitrous oxide
CAS No.
79-46-9
Formula
Relative
Response
C3H7NO2
ZR
10024-97-2
N2O
ZR
Nonane, n-
111-84-2
C9H20
1.3
Norbornadiene, 2,5-
121-46-0
C7H8
0.6
Octachloronaphthalene
2234-13-1
C10Cl8
1
Octane, n-
111-65-9
C8H18
1.6
Octene, 1-
111-66-0
C8H16
0.7
Oxalic acid
144-62-7
C2H2O4
ZR
Oxalonitrile
460-19-5
C2N2
ZR
Oxydiethanol 2,2-
111-46-6
C4H10O3
4
O2
ZR
O3
ZR
Oxygen
Ozone
Paraffin wax, fume
10028-15-6
8002-74-2
1
Paraffins, normal
64771-72-8
1
Pentacarbonyl iron
13463-40-6
FeC5O5
1
Pentachloroethane
76-01-7
C2HCl5
ZR
Pentachlorofluoroethane
354-56-3
C2Cl5F
ZR
Pentafluoroethane
354-33-6
C2HF5
ZR
Pentan-2-one
107-87-9
C5H10O
0.8
Pentan-3-one
96-22-0
C5H10O
0.8
Pentandione, 2,4-
123-54-6
C5H8O2
0.8
Pentane, n-
109-66-0
C5H12
7.9
Peracetic acid
79-21-0
C2H4O3
2
Perchloryl fluoride
7616-94-6
Cl03F
ZR
Perfluoropropane
76-19-7
C3F8
ZR
Petroleum ether
0.9
Phenol
108-95-2
C6H6O
Phenyl propene, 2-
98-83-9
C9H10
1.2
0.4
Phenyl-2,3-epoxypropyl ether
122-60-1
C9H10O2
0.8
Phenylenediamine, p-
106-50-3
C6H8N2
0.6
Phosgene
75-44-5
COCl2
ZR
Phosphine
7803-51-2
PH3
2
Picoline, 3-
108-99-6
C6H7N
0.9
Pinene, alpha
80-56-8
C10H16
0.3
Pinene, beta
127-91-3
C10H16
0.3
Piperidine
110-89-4
C5H11N
0.9
Piperylene
504-60-9
C5H8
0.7
Prop-2-yn-1-ol
107-19-7
C3H4O
1.3
Propan-1-ol
71-23-8
C3H8O
4.8
Propane
74-98-6
C3H8
ZR
Propane-1,2-diol, total
57-55-6
C3H8O2
10
Propene
115-07-1
C3H6
1.4
Propionaldehyde
123-38-6
C3H6O
1.7
Propionic acid
79-09-4
C3H6O2
8
Propyl acetate, n-
109-60-4
C5H10O2
2.5
Propylene dinitrate
6423-43-4 C3H6N2O6
110 • Detail Settings Button
ZR
Gas/ VOC
CAS No.
Formula
Propylene oxide
75-56-9
C3H6O
Propyleneimine
75-55-8
C3H7N
1.3
Pyridine
110-86-1
C5H5N
0.8
Pyridylamine 2-
504-29-0
C5H6N2
0.8
Silane
7803-62-5
SiH4
ZR
Sodium fluoroacetate
62-74-8
C2H2O2FNa
ZR
Styrene
100-42-5
C8H8
0.4
9/5/46
SO2
ZR
Sulphur hexafluoride
2551-62-4
SF6
ZR
Sulphur tetrafluoride
7783-60-0
SF4
ZR
Sulphuric acid
7664-93-9
H2SO4
ZR
Sulphuryl fluoride
2699-79-8
SO2F2
ZR
C18H14
0.6
Sulphur dioxide
Terphenyls
Relative
Response
7
Terpinolene
586-62-9
C10H16
0.5
Tert-butanol
75-65-0
C4H10O
2.6
Tetrabromoethane, 1,1,2,2-
79-27-6
C2H2Br4
2
Tetracarbonylnickel
Tetrachloro-1,2difluoroethane, 1,1,2,2Tetrachloro-1-fluoroethane,
1,1,2,2Tetrachloro-2,2difluoroethane, 1,1,1,2Tetrachloro-2-fluoroethane,
1,1,1,2Tetrachloroethane, 1,1,1,2Tetrachloroethane, 1,1,2,2Tetrachloroethylene
Tetrachloronaphthalenes, all
isomers
Tetraethyl orthosilicate
13463-39-3
NiC4O4
1
76-12-0
C2Cl4F2
ZR
354-14-3
C2HCl4F
ZR
76-11-9
C2Cl4F2
ZR
354-11-0
C2HCl4F
ZR
630-20-6
C2H2Cl4
ZR
79-34-5
C2H2Cl4
ZR
127-18-4
C2Cl4
0.7
20020-02-4
C10H4Cl4
1
78-10-4
C8H20O4Si
2
Tetraethyllead
78-00-2
C8H20Pb
ZR
Tetrafluoroethane, 1,1,1,2-
811-97-2
C2H2F4
ZR
Tetrafluoroethane, 1,1,2,2-
359-35-3
C2H2F4
ZR
Tetrafluoroethylene
116-14-3
C2F4
1
Tetrafluoromethane
75-73-0
CF4
ZR
Tetrahydrofuran
109-99-9
C4H8O
1.6
Tetramethyl orthosilicate
681-84-5
C4H12O4Si
ZR
Tetramethyl succinonitrile
3333-52-6
C8H12N2
1
Therminol
Thionyl chloride
1
9/7/19
SOCl2
ZR
Toluene
108-88-3
C7H8
0.5
Toluene-2,4-diisocyanate
584-84-9
C9H6N2O2
1.6
Toluenesulphonyl chloride, p-
98-59-9
3
0.5
5
Toluidine, o-
95-53-4
C7H7SO2
Cl
C7H9N
Tributyl phosphate
126-73-8
C12H27O4P
Detail Settings Button • 111
Gas/ VOC
CAS No.
Formula
Tributylamine
102-82-9
C12H27N
Relative
Response
1
Trichloro-1,1-difluoroethane,
1,2,2Trichloro-1,2-difluoroethane,
1,1,2Trichloro-2,2-difluoroethane,
1,1,1Trichloro-2-fluoroethane,
1,1,2Trichlorobenzene 1,2,4-
354-21-2
C2HCl3F2
ZR
354-15-4
C2HCl3F2
ZR
354-12-1
C2HCl3F2
ZR
359-28-4
C2H2Cl3F
ZR
120-82-1
C6H3Cl3
0.6
Trichloroethane, 1,1,1-
71-55-6
C2H3Cl3
ZR
Trichloroethane, 1,1,2-
79-00-5
C2H3Cl3
ZR
Trichloroethylene
79-01-6
C2HCl3
0.7
Trichlorofluoromethane
75-69-4
CCl3F
ZR
Trichloronitromethane
76-06-2
CCl3NO2
ZR
Trichlorophenoxyacetic acid,
2,4,5Trichloropropane 1,2,3-
93-76-5
C8H5O3Cl 3
1
96-18-4
C3H5Cl3
ZR
Trichlorotrifluoroethane, 1,1,1-
354-58-5
C2Cl3F3
ZR
Trichlorotrifluoroethane, 1,1,2-
76-13-1
C2Cl3F3
ZR
Triethylamine
121-44-8
C6H15N
0.9
Trifluoroethane, 1,1,1-
420-46-2
C2H3F3
ZR
Trifluoroethane, 1,1,2-
430-66-0
C2H3F3
ZR
Trifluoroethanol, 2,2,2-
75-89-8
C2H3F3O
ZR
Trifluoromethane
75-46-7
CHF3
ZR
Trimethylamine
53-50-3
C3H9N
0.5
C9H12
0.3
Trimethylbenzene mixtures
Trimethylbenzene, 1,3,5-
108-67-8
C9H12
0.3
Trinitrotoluene 2,4,6-
118-96-7
C7H5N3O6
ZR
Turpentine
8006-64-2
C10H16
0.6
TVOC
1
Undecane, n-
1120-21-4
C11H24
0.9
Vinyl acetate
108-05-2
C4H6O2
1.1
Vinyl bromide
593-60-2
C2H3Br
1
Vinyl chloride
75-01-4
C2H3Cl
2.1
Vinyl-2-pyrrolidinone, 1-
88-12-0
C6H9NO
0.9
Xylene mixed isomers
1330-20-7
C8H10
0.4
Xylene, m-
108-38-3
C8H10
0.4
Xylene, o-
95-47-6
C8H10
0.6
Xylene, p-
106-42-3
C8H10
0.6
Xylidine, all
1300-73-8
C8H11N
0.7
112 • Detail Settings Button
Changing the Appearance
of the Program Screens
To change how information is displayed in the program (e.g.,
text font or graph colors), use the program’s Set Window. Follow
the steps below to make changes.
1. Launch the Eagle 2 Data Logger Management Program.
2. Click the Set button to display the Set window. Use the Font
And Color Frame in the left side of the window to change
fonts and graph colors.
Click to change font type
Choose these options to change the
graph colors for the target gases
Figure 84: Set Window, Changing Fonts and Graph Colors
Changing the Appearance of the Program Screens • 113
3. Specify new fonts by clicking the button with the name of a
font inscribed on it. This action will display the Font Window.
Choose the font type, style, size, and script, then click OK.
Figure 85: Font Window
114 • Changing the Appearance of the Program Screens
4. Select the colors used to graph the various target gases in
the interval trend and alarm trend data files by clicking the
appropriate Graph Color button on the left side of the Set
Window in the Font and Color frame. The six Graph Color
buttons correspond to the 6 possible Eagle 2 channels. From
top to bottom, they correspond to channels 1-6.
Figure 86: Color and Custom Color Windows
• The Color Window shown on the left above appears when
the Graph Color button is clicked.
• If you want to define a custom color, click the Define
Custom Colors button and the Custom Color Window
shown on the right above replaces the Color Window.
5. After making the desired changes, click OK.
6. The changes you have made will take effect after you exit
and restart the program.
Changing the Appearance of the Program Screens • 115
Spare Parts List
Table 6: Spare Parts List
Part Number
Description
47-5027RK
Cable, USB/IrDA adapter
71-0170RK
Eagle 2 Data Logger Management Program Operator’s
Manual (this document)
71-8003RK
Eagle 2 Product CD, Includes the Eagle 2 Data Logger
Management Program, the Eagle 2 Maintenance Program, and Operator’s Manuals for Each
116 • Spare Parts List