1. Training Presentation
EPOCH 600
Training Presentation

2. EPOCH 600 EPOCH 600 Introduction
Olympus NDT is proud to introduce the latest innovation in the portable flaw detector line:
EPOCH 600

3. EPOCH 600 Introduction- Overview
The EPOCH 600 provides a powerful combination of performance and economy as a class-leading mid range flaw detector:
Proven EPOCH 100% digital technology
Vivid, transflective VGA display
IP66 or IP67 rating
EN compliant
Horizontal layout with intuitive EPOCH user interface

4. EPOCH 600 Introduction- Configurations
The EPOCH 600 allows multiple configurations for all user preferences:
BNC or LEMO® 1 transducer connectors
Optional Analog Output
English, Japanese, Chinese or Symbolic keypad overlays

5. Pulser/Receiver Functions

6. Pulser Performance EPOCH 600 Pulser Features:
PerfectSquare™ Tunable Square Wave Pulser Technology: standard
Pulser energy selection of 100V, 200V, 300V or 400V
Auto or Manual PRF adjustment from 10Hz to 2000Hz: standard
Single-Shot Measurement Architecture: The EPOCH 600 Series maintains the high standard set by the EPOCH XT, providing measurement rate equivalent to PRF rate at all PRF settings
Pulser Design designed for compliance to EN

7. Receiver Performance EPOCH 600 Receiver Features:
Digital high dynamic range receiver
Gain adjustment over full 110dB range while frozen
Gate adjustment with digital measurements while frozen
High dynamic range for DAC/TVG and DGS/AVG
Eight digital receiver filter settings, EN compliant
0.2 – 10 MHz
2.0 – 21.5 MHz
8.0 – 26.5 MHz
0.5 – 4.0 MHz
Analog Output: optional
Programmable 1V or 10V scaled output for amplitude or thickness measurements
0.2 – 1.2 MHz
1.5 – 8.5 MHz
5 – 15 MHz
DC – 10 MHz

8. Gate Settings
Gate 1 and Gate 2 Independent Measurements Gates: standard
Echo-to-Echo Measurement with Gate 2 Tracking: standard
Interface Gate: optional
Independent Gate Alarms
Positive, Negative, MinDepth
Audible and Visual Alarm on LEDs 1 & 2
Alarm output from 9-pin D-sub connector on back of unit
Gate 1 = Pin 8, Gate 2 = Pin 9

9. Special Waveform Modes
The EPOCH 600 provides multiple methods of displaying acquired A-scans to ensure the information displayed always represents the most important and relevant data for the inspection.
The methods included are:
Composite A-scan
Max Amplitude
Min Thickness
Averaged A-scan

10. Special Waveform Modes
To Access the Special Waveform Modes:
In the Display Setup menu, press [F2] Meas Setup
Press [P6] to enter the Special menu
Use the knob, arrows, or the P-keys to change the A-Scan Mode
Press the [NEXT GROUP] key
Use the knob, arrows, or the P-keys to change Averaging
Press the [ESC] key to return to the main screen

11. Composite A-Scan Mode
Composite A-scan – Standard display mode from the EPOCH XT, this feature displays all A-scans acquired in between screen update rates (multiple A-scans when PRF > 60Hz) and overlays them together on the screen.
Even at high PRF, the operator will not miss a single indication!
Can create enveloping effect with fast scanning
Screen Updates
Individual A-scans
acquired at PRF
Information Displayed
Composite A-scan Mode

12. Maximum Amplitude A-Scan Mode
Max Amplitude – Analyzes acquired A-scans between display updates and displays only the A-scan with the highest gated amplitude reading.
Cleans up signal noise in applications where highest amplitude readings are the key factor for inspection.
Does not display all acquired A-scans
Screen Updates
Individual A-scans
acquired at PRF
Maximum
Amplitude
A-scan
Maximum
Amplitude
A-scan
Information Displayed
Max Amplitude Mode

13. Minimum Thickness A-Scan Mode
Min Thickness – Analyzes acquired A-scans between display updates and displays only the A-scan with the minimum thickness reading.
Cleans up signal noise ratio for more precise thickness measurements when minimum thickness is the key factor for inspection.
Does not display all acquired A-scans
Screen Updates
Individual A-scans
acquired at PRF
Minimum
Thickness
A-scan
Minimum
Thickness
A-scan
Information Displayed
Min Thickness Mode

14. A-Scan Averaging
Averaged A-scan – New functionality allows the operator to view an average of acquired A-scans.
The user can select the precision of the averaging, choosing between 2X, 4X, 8X, 16X, or 32X averaging to remove spurious noise signals from the A-Scan while maintaining relevant signals.
Note: At higher averaging rates, the screen update rate may be less than 60Hz (depending on the PRF value).
16X Averaging
Averaging Off

15. EPOCH 600 Performance Features: Summary
The EPOCH 600 maintains the performance of current generation EPOCH flaw detectors in a highly portable package:
Standard square wave pulser with PerfectSquare™ technology
Digital receiver filters for excellent signal to noise ratio
Digital high dynamic range receiver for unmatched signal stability
EN compliance
Single shot waveform acquisitions up to 2000 Hz PRF
Composite, Max Amplitude and Min Thickness A-Scan Display Modes
Waveform Averaging
Standard software features including:
Dynamic DAC/TVG
Onboard DGS/AVG
Curved Surface Correction
Auto or Manual PRF Adjustment
Gate 2 Tracking and Echo to Echo Measurements
Optional software features including:
AWS D1.1/D1.5 Rating
Template Storage
API 5UE
Waveform Averaging
Expanded Data Logger
Interface Gate
Corrosion Module
Backwall Echo Attenuator (BEA)

16. PHYSICAL FEATURES

17. Improved Display Quality
The EPOCH 600 features a new, high quality display
Full VGA resolution (640 x 480 pixels)
Vibrant, bright colors
Transflective for excellent outdoor visibility
Low power consumption to improve overall battery life

18. New Enclosure Design
The EPOCH 600 features a brand new design on a traditional concept
New, Sleek Design
New color scheme
Keypad updated with contemporary style and feel
Horizontal Layout
Optimizes A-scan viewing area
Intuitive push-button navigation
Broad market appeal
Size and Weight
1.68 kg (3.72 lbs)
236 mm x 167 mm x 70 mm (9.3 in x 6.57 in x 2.76 in)
Over 50% lighter and 40% smaller by volume than the EPOCH 1000!

19. Knob or Navigation Pad
The EPOCH 600 is available with either an adjustment knob or navigation pad to meet the preference of any user!

20. Continuous-Position Stand
The pipe stand for the EPOCH 600 utilizes a brand new design:
Friction hinges for continuous positioning from 0° to 180°
Recessed instrument housing to hide closed stand
90° bend for improved stability with minimized opened dimension

21. Environmental Standards
IP Rated:
IP66 (knob configuration)
IP67 (navigation pad configuration)
MIL-STD-810F
Explosive Atmosphere
Drop Test
Storage and Operating Temperatures
Shock and Vibration tested to IEC 60068

22. Inputs and Outputs: Office Door
The EPOCH 600 has several data input and output capabilities.
USB On-the-GO (OTG)
PC communication
Direct printing to PCL 5 USB printers
Micro SD card
2GB external (removable)
2GB internal (data retrieval even if instrument is damaged)

23. Inputs and Outputs: Back of Instrument
The EPOCH 600 has several data input and output capabilities.
VGA Output
15-pin connector
Combination RS232 and Alarm Output
9-pin connector
Analog Output (Optional)
Single 0-1V or 0-10V Analog Output signal
Analog Out

24. INSTRUMENT ACCESSORIES

25. Included Documentation
The EPOCH 600 offers three forms of standard reference documentation:
Quick Start Guide
New document offered for EPOCH flaw detector line
Provides essential overview topics such as:
What’s in the box?
Power and charging options
User interface overview
Reference guide to flags and symbols
Intended to provide enough information for a seasoned flaw detector user to begin daily functions

26. Included Documentation
The EPOCH 600 offers three forms of standard reference documentation:
Basic Operation Manual
Concise operator’s guide for all major functions (60-70 pages)
Printed version included with every instrument
Translations available in:
English, Spanish, French, German, Italian, Japanese, Chinese
Full Operation Manual
Detailed and comprehensive operation manual
Includes Basic Operation Manual as first section
Included with every instrument as PDF file on a CD
All available translations are included with every instrument

27. Transport Case and Input and Output Cables
USB OTG Cables
Cable for PC Communication (Type: Mini AB to A)
EPLTC-C-USB-A-6 (U )
Cable for Printing (Type: Mini AB to B)
EPLTC-C-USB-B-6 (U )
VGA Output Cable
600-C-VGA-5 (U )
Alarm Output Cable
EP1000-C-9OUT-6 (U )
RS232 Cable
600-C-RS232-5 (U )
Transport Case
Blow Molded to Accommodate
Instrument
Transducers
Small cables and accessories
Operator’s Manual
Instrument Charger
Included in Instrument Price
Part Number: 600-TC-S (U )

28. Batteries and Battery Chargers
Standard Lithium Ion “smart” battery
Part Number: 600-BAT-L (U )
One (1) included with each instrument
Estimated Battery life (Standard Settings): hours
May be charged inside instrument. Recharge time estimated 2-3 hours
Standard AC-DC charger adapter
Part Number: EP-MCA (U8 varies based on power cord selected)
Same as charger/adapter used for all current EPOCH models and new 38DLPLUS corrosion gage
AA Alkaline Battery Tray
Accommodates 8 ‘AA’ size alkaline batteries for back-up remote power
Up to 3 hours of battery life
Part Number: 600-BAT-AA (U )

29. Battery Installation

30. External Battery Charger
Optional external battery charger
Part Number: EPXT-EC (U8 varies based on power cord selected)
Same as external charger used for EPOCH 1000 Series, EPOCH XT, EPOCH LTC
Recharge time 2-3 hours
Includes battery calibration feature to restore batteries to near-original capacity

31. Compatible Accessories
Other compatible accessories include:
Micro SD Memory Card (Replacement)
Part Number: MICROSD-ADP-2GB (U )
Includes Micro to standard SD adapter
Chest Harness
Part Number: EP4/CH (U )
Display Protectors
Part Number: 600-DP (U )
Replacement Pipe Stand Kit
Part Number: 600-STAND (U )
Include pipe stand, hinges, mounting brackets and screws

32. OPERATION AND USER INTERFACE

33. Instrument Layout
The overall layout of the EPOCH 600 is similar to that of the EPOCH 1000 Series.
Horizontal (landscape) design is a more basic version of EP1000 user interface
Keypad has fewer direct access keys than the EPOCH 1000 and therefore has a more menu-driven approach (similar to the EPOCH LTC)

34. Instrument Layout
The EPOCH 600 employs a unique combination of controls and navigation features to produce an intuitive and simple user interface.
Simple menu system with minimal sub-menus
Basic navigation using the keypad
Direct access keys for frequently used functions
Parameter adjustment using the knob (or arrow keys)

35. Instrument Layout
The display is laid out to optimize A-scan presentation while providing clearly visible measurements, menus, and parameter labels
Calibration/Setup parameters are accessed through the different menus on the unit
When inspecting, the most frequently used keys/functions are directly accessible from keypad (Gates, Range, Auto-XX etc)

36. Instrument Layout
In order to accommodate different user needs and preferences, the EPOCH 600 is available in two hardware configurations:
Adjustment knob (similar to EP1000 Series)
Navigation pad with arrows (similar to EPXT and EPLTC units)
Both unit configurations have the same software user interface but use different methods of parameter adjustment (knob and arrows)

37. General Overview Knob Lock Power Status LED Alarm LEDs Adjustment Knob
Function Keys
Direct Access Keys
Parameter Keys
A-Scan Waveform

38. Micro SD Card Indicator
User Interface
Menu Groups
Micro SD Card Indicator
Battery Indicator
Group Menu Number
Menu Parameters (Adjustable)

39. User Interface Gain Indicator Up to Five Measurement Boxes Range and
Direct Access
Parameter Box
A-scan Measurement
Gate 1
A-scan Measurement
Gate 2

40. Instrument Navigation
F Group Keys
Vertical F keys activate the corresponding Group menu
P Parameter Keys
Horizontal P keys highlight the parameter above for adjustment
Horizontal P keys activate/open the parameter function/menu above

41. User Interface
Standard Group Menus

42. Instrument Navigation
Next Group Key
Used to scroll through group menus
Allows for quick and easy access to all the different menu group functions
Used to navigate through parameters in a menu

43. Instrument Navigation
Direct Access Keys
Direct access keys are located on the left side of the keypad
Allow direct control over commonly adjusted parameters, including
Gate Position
Screen Range
Gain Level
Peak Memory
Auto-XX%
Save
The Navigation pad is similar to previous EPOCH units (1000 Series, XT, LTC) to provide easy transitions within the EPOCH product line
EPOCH 600 Knob
EPOCH 600 Navigation Pad

44. Instrument Navigation
Auto-XX% Key
Automatically adjusts gated signal amplitude to XX% of Full Screen Height for maximum flaw inspection efficiency
Allows direct access to automatic gain adjustment of gated signal, even when Gate parameter adjustment is not active
User no longer has to use Gate menu to access Auto-XX%
Applies to active Gate or last active Gate

45. Instrument Navigation
Check and Escape Keys
The EPOCH 600 features Check and Escape keys (as on the EPOCH 1000 Series)
The CHECK key performs the following functions:
Toggle between coarse and fine parameter adjustment (Knob version only)
Confirms actions in the data logger

46. Instrument Navigation
Check and Escape Keys (cont.)
The ESCAPE key performs the following functions:
Exits menus
Returns to the “Home” position from any menu (top of Basic menu)

47. Instrument Navigation
Direct Parameter Escape
Returns to previous menu from any direct access parameter
Both the NEXT GROUP and ESCAPE keys perform this function
DAC/TVG Menu
GATES key pressed
ESC or NEXT GROUP returns to DAC/TVG Menu

48. Instrument Navigation
LED Indicator Lights
The EPOCH 600 provides one power and three alarm indicator lights located on the front panel above the display window
The alarm indicators illuminate in red when the corresponding date alarm is triggered
The power indicator illuminates in red when the internal battery is charging, and in green when the battery is fully charged
Gate 1 Alarm Indicator
Power Indicator
Gate 2 Alarm Indicator

49. Instrument Navigation
Adjustment Knob
The adjustment knob on the EPOCH 600, is responsible for parameter adjustment and value slewing.
Allows the user to adjust values such as angle, range, gain, velocity, etc, up and down in either coarse or fine increments.

50. Instrument Navigation
Knob Lock
The user has the ability to lock the knob to prevent accidental parameter value changes during an inspection.
When the LOCK key is pressed, an indicator will show on the top of the screen
All parameters will be locked for adjustment, indicated by a strikeout line through the parameter text
LOCK Indicator
Locked Parameter
LOCK Key

51. Instrument Navigation
Arrow Keys
The arrow keys on the navigation pad perform the same functions as the knob and are used for parameter adjustment
Adjust the value of a selected parameter
UP/DOWN arrows provide coarse adjustment while the LEFT/RIGHT arrows provide fine adjustment
Enter alphanumeric characters for datalogging

52. Instrument Navigation
Parameter Menu Navigation
Next Group key allows navigation through entire menu
In some menus, knob or left/right arrows adjusts item between preset values, such as grid display modes
In other menus, knob or left/right arrows adjusts numeric value of highlighted item
Preset values for a given parameter are available for direct access over P parameter keys at bottom of screen

53. Instrument Navigation
Coarse and Fine Adjustment
Coarse and Fine adjustment are available for most adjustable parameters on the EPOCH 600.
Knob Version
Once a parameter is highlighted for adjustment, the user can toggle between Coarse and Fine adjustment of the parameter using the key.
If the parameter title is [bracketed] it is being adjusted in coarse steps.
If the parameter title is not bracketed, it is being adjusted in fine steps
Navigation Pad Version
Once a parameter is highlighted for adjustment
Double UP and DOWN arrows provide coarse adjustment
Single LEFT and RIGHT arrows provide fine adjustment
Coarse Adjustment
Fine Adjustment

54. Editable Parameters
This feature allows the user to customize the preset values that are displayed during coarse adjustment for these specific parameters.
To access the Editable Parameters menu, select Inst Setup > Edit Parameters.

55. Editable Parameters Editable Parameters:
The instrument comes with certain preset values for each of the parameters, but the user can change any of these values as necessary to meet their needs.
Users can add up to 7 preset values for each parameter
Except for Gain Step, which only allows 2 preset values
Editable Parameters:
Gain Step
Gain
Range
Delay
Freq
Angle
Thick
X Value

56. Editable Parameters- Changing Values
To change a preset value:
Using the NEXT GROUP key, select the value you want to edit and use the adjustment knob or arrow keys to adjust the value.
The values can be adjusted in coarse or fine increments by pressing the CHECK key or using the corresponding arrow keys.
Press [P1] to Clear the currently selected value.
NOTE: For parameters that have different values in Metric and English units (e.g. Velocity), the user can store different values in each measurement system. Only the values for the current units setting will be displayed in the Editable Parameters menu.

57. Editable Parameters- Coarse Adjustment
Adjusting the parameters below using Coarse adjustment will toggle through the preset values from the Editable Parameters screen:
Velocity
Frequency
Angle
Thick
X-Value
Fine adjustment will scroll through all non-preset values.
Coarse Adjustment
Fine Adjustment

58. Coarse Adjustment “Rounding”
When changing parameter values using Coarse adjustment, all digits after the digit being adjusted are set to zero for the following parameters:
Range
Delay
Zero
Fine adjustment will allow the user to modify the remaining digits.
Fine Adjustment
Coarse Adjustment

59. Software Option Activation
The EPOCH 600 has a set of software options that can be purchased to enhance or add features to the instrument. These include:
AWS D1.1/D1.5
Template Storage
API 5UE
Expanded Datalogger
Waveform Averaging
IF Gate
Corrosion Module
Backwall Echo Attenuator
These software options can be purchased along with the instrument or can be activated remotely in the field if purchased at a later date.
Once a software option has been purchased, it will show as Licensed in the Inst Setup > Software Options menu.
This menu is also used to enter activation codes when options are purchased.

60. TROUBLESHOOTING

61. Troubleshooting Techniques
Instrument Resets
The EPOCH 600 Series has several instrument resets built into the software
Location: In the Files menu, press [F2] for Manage, then select [P1] for Reset
Corrects symptoms:
Parameter cannot be adjusted
Function/parameter seems to be missing
Instrument is operational but “acting funny”
Resets include:
Measurement Reset – maintains data logger, restores default parameters
Storage – clears data logger, maintains live parameters
Master– clears data logger, restores default parameters (combination of Measurement and Storage)

62. STRAIGHT BEAM CALIBRATION

63. Required Items Transducer Test Block Cable Couplant A109S-RM
Insert picture
Transducer
A109S-RM
Test Block
2214E (5-step in)
Cable
BCM-74-6
Couplant
B-2

64. Initial Settings
First the user must set the parameters on the unit so that the correct waveforms will show on screen.
Basic Menu
[P1] Velocity in/µs (long. wave in steel)
[P2] Zero µs
[P3] Range – in
Pulser Menu
[P1] PRF Mode- Auto
[P3] Energy- 100V
[P4] Damping- 50 Ω
[P5] Mode- P/E (pulse-echo)
[P6] Pulser- Square
[P7] Frequency- 5MHz
Receiver Menu
[P1] Filter- 1.5 – 8.5 MHz
[P2] Rectification- Full

65. Zero Calibration Set the Gain to 12.0dB
Couple the transducer to the in step
Set Gate 1 so that it surrounds the first backwall echo from the in step
Use Auto-XX to adjust the gain so that the signal is at 80% FSH

66. Zero Calibration
In the Basic menu, press [F5] Auto Cal to bring up the Calibration parameters
Press [P1] and set the Type to Thickness
(If more than just Gate 1 is active you will have other options for Type)
Press [P3] for CAL Zero
Use the adjustment knob (or arrow keys) to set the Cal Zero parameter to 0.200
Press [P3] to Continue on to the velocity calibration

67. Velocity Calibration Couple the transducer to the 0.500 in step
Set Gate 1 so that it surrounds the first backwall echo from the in step
Use Auto-XX to adjust the gain so that the signal is at 80% FSH
Note that the previously entered value is displayed for reference during part 2 of calibration.

68. Velocity Calibration Press [P2] for CAL Velocity
Use the adjustment knob (or arrow keys) to set the Cal Velocity parameter to 0.500
Press [P2] to select Done and complete the calibration
Adjust the Range back to the starting value of in

69. Calibration Complete!
Verify that your unit is properly calibrated by checking the thickness measurement at each step on the block.
NOTE: Make sure to move the gate so it surrounds the first backwall echo for each step you are on.

70. ANGLE BEAM CALIBRATION

71. Required Items Materials: TRANSDUCER + WEDGE TEST BLOCK CABLE COUPLANT
A431S-SM
ABWS-6-45
TEST BLOCK
TB7541-1
CABLE
LCB-74-6
COUPLANT
B-2

72. Calibration Steps 4 Steps for an Angle Beam Calibration
Locate the Beam Index Point (BIP) of the Probe.
Verify the Refracted Angle
Calibrate for Distance (Using the Auto-Cal Feature)
Calibrate for Sensitivity

73. Initial Settings
First the user must set the parameters on the unit so that the correct waveforms will show on screen.
Basic Menu
[P1] Velocity in/µs (shear wave in steel)
[P2] Zero µs
[P3] Range – in
Pulser Menu
[P1] PRF Mode- Auto
[P3] Energy- 200V
[P4] Damping- 50 Ω
[P5] Mode- P/E (pulse-echo)
[P6] Pulser- Square
[P7] Frequency- 5MHz
Receiver Menu
[P1] Filter- Standard
[P2] Rectification-Full
Trig Menu
[P1] Angle- 45.0

74. Locating the Beam Index Point
Step 1/4
Align the wedge with the zero mark on the “IIW Type I Block”
Move the transducer forward and backward until the echo amplitude from the 4” arc is peaked (The Peak Memory function can be used for this by pressing [PEAK MEM])
After the signal has been peaked, mark on the wedge directly over the zero mark on the IIW. This is the Beam Index Point.

75. Verifying the Refracted Angle
Step 2/4
Position the transducer over the appropriate angle mark on the IIW Block (In this case it is the 45 deg located on the bottom side of the block).
Move the transducer forward and backward to “peak up” echo from the large circular hole in the block. Peak Memory aids in this process by pressing [PEAK MEM].

76. Verifying the Refracted Angle
Step 2/4
After the signal is peaked, hold the transducer stationary. The Beam Index Point on the wedge will be located above an angle marker on the IIW block.
This is the REFRACTED ANGLE (Beta) for the transducer and wedge.
If the Beta Value differs from the one initially entered, enter the proper angle under the Trig menu by pressing [P1] Angle

77. Calibrating for Distance
Step 3/4
Couple the transducer to the IIW Block so that the Beam Index Point is directly over the 0 degree mark. 4” 1”

78. Calibrating for Distance
Step 3/4
Position Gate 1 over the 4 in. reference echo and use Auto-XX to adjust to 80% screen height.
In the Basic menu, press [F5] Auto Cal to bring up the Calibration parameters
Press [P1] and set the CAL Mode to Soundpath
(If more than just Gate 1 is active you will have other options for CAL Mode)
Press [P3] for CAL Zero
Use the adjustment knob (or arrow keys) to set the Cal Zero parameter to 4.000in
Press [P3] to Continue on to the velocity calibration

79. Calibrating for Distance
Step 3/4 4” 1”
Without moving the probe, position gate over the 9” reflection echo.
You may have to increase the Gain first in order to see the 9 in. echo
Use the Auto XX% feature to bring the 9” reflection to the desired screen height

80. Calibrating for Distance
Step 3/4
Press [P2] for CAL Velocity
Use the adjustment knob (or arrow keys) to set the Cal Velocity parameter to 9.000
Press [P2] to select Done and complete the calibration
Adjust the Range back to the starting value of in

81. Calibrating for Sensitivity
Step 4/4
0.060” side
drilled hole
Flip the IIW block over and face the transducer toward the in. side drilled hole.
Set the Range to 2.000in
Peak up the echo from the side drilled hole to 80% screen height.
The Peak Memory function can be used for this by pressing [PEAK MEM]
Press [2nd F], [dB] (REF dB) to lock in the instrument’s Reference Gain and enable the Scanning Gain function.
The Shear Wave Calibration is now complete.

82. DATA LOGGER

83. Data Logger
The EPOCH 600 Data Logger is managed in a separate file menu similar to the EPOCH 1000 Series. This menu is accessed by scrolling to menu 5 and selecting [F1] for File

84. Data Logger File Types The standard Data Logger has two file types:
Incremental Files (INC): Name the file and give the instrument a starting ID. As the operator saves the ID will increment automatically.
Calibration Files (CAL): These files store only one ID.
There is an Expanded Data Logger option available that provides corrosion style data logger file types
These file types include: Sequential, 2D-Grid, Boiler, etc
The part number for this option is EP600-XDATA (U )

85. Data Logger Storage Data Logger Storage
2 GB of onboard memory (practically unlimited)
Onboard memory captured on Micro SD card mounted to PCB. In the event of damage to the instrument, data logger contents can be rescued by removing card from PCB at an authorized service location.
Default Incremental File – NONAME00
The EPOCH 600 has a default incremental file called NONAME00. This allows the operator to begin storing data immediately on power-up. The filename can be changed later for reporting purposes.

86. File Operations- Creating a File
The operator uses the Create menu to setup and create new files. The [NEXT GROUP] key is used to move between fields.
NOTE: Fields that are required for file creation are marked with an *.
To create a file:
Select the file type (INC or CAL)
Enter the file name
Enter a Description, Inspector ID, and Location note if desired
Enter an ID prefix if desired (INC files only)
Enter the Start ID (INC files only)
In the Create field, choose one of the create options shown above the P-keys

87. File Operations- Virtual Keypad
To enter alphanumeric characters on the EPOCH 600, the [P1] Edit key is pressed to bring up the virtual keypad.
Using the knob or arrow keys, the user selects the character they want to type.
Press [F5] INS to Insert the selected character into the highlighted field
Use [F1] << and [F2] >> to scroll through the typed characters in the selected field
Press [F4] DEL to Delete the selected character
Press [F1] Edit again to turn off the virtual keypad, or press [NEXT GROUP] to move to the next field

88. File Operations- Create Menu
When creating a file, the user must select one of three options listed above the P-keys:
[P1] = Create
[P2] = Create & Open
[P3] = Create & Save
Create:
This will simply create the file and return the user to the main screen.
The user must then open the file prior to saving data.
Create & Open:
This will create the file, open it, and return the user to the live screen to begin saving data.
Typically used for data files.
Create & Save:
This will create the file and save the current instrument setup.
Typically used for CAL files.

89. File Operations- Open Menu
The operator uses the Open menu for multiple functions including opening and recalling previously created files. The following slides describe the menu functions.

90. File Operations- Open Menu
[P1] Details
Allows the operator to view information about the file including Description, Inspector ID, Location Note, Creation Date, and Total ID Count.
[P2] Open
Opens the selected file and returns the operator to the live screen. Optionally, File Open & Recall can be activated, which also sets the active parameters of the saved ID. This is accessed through Inst Setup > General.

91. File Operations- Open Menu
[P3] Contents
Displays the waveform, measurements, and setup parameters for the selected file. For INC files, the user can select which specific ID they want to view. Setup data can also be viewed and recalled from this screen.
Pressing [P1] will toggle between the stored waveform and setup parameters.

92. File Operations- Open Menu
[P4] Summary
Displays a list of all the saved measurements for all the IDs in the file. The user can also view a statistical report of the measurements in the file.

93. File Operations- Saving Data
The operator can save data whenever there is an active file and an ID has been entered.
The NONAME00 file is automatically created on every EP600 unit to ensure that there is always an active “save to” location open.)
To save data into a file, press [2nd F] [FREEZE] (SAVE).
If you are saving data to an incremental file, the ID will automatically increment to the next ID after saving.
When you save, the EP600 saves the following information:
File Name ID
Measurements (up to 5)
A-Scan waveform
All instrument setup parameters
Alarm information
Any display flags
Gate positions
Gate measurement mode icons
Leg indicators for both gates
Peak memory or peak hold A-Scans
Software features/option setups

94. File Operations- Parameters Recall
As an alternative to simultaneously opening and recalling a file, the user can recall a stored setup from the Contents screen (INC and CAL files) or using the Quick Recall feature (CAL files only).
In the Contents screen, select the ID with the setup to be recalled, and press [P2] Recall.
For Calibration files, simply press [P4] Quick Recall from the datalogger menu. A list of CAL files in the instrument will be displayed. Then press [P1] to Recall the selected CAL file and return to the live screen.

95. File Operations- Manage Menu
Reset – Instrument resets (Parameters, Master, etc)
Export – New feature allowing individual file export to Micro SD card
Import – New feature allowing individual file import from Micro SD card
Edit – Allows for editing of file name and optional description parameters
Copy – Creates a duplicate of a selected file
Delete – Deletes a selected file

96. File Operations- Export
When exporting a file, the user must select one of three file types:
Binary files include all saved parameter and waveform information and can be shared between EPOCH 600 units
CSV files include parameter data only for viewing in Microsoft Excel
XML files contains parameter and waveform data for viewing in external software programs
To Export a file:
Select Manage > Export
Choose the desired file and press [NEXT GROUP]
Select the File Type
Press [NEXT GROUP], then [P1]

97. File Operations- Import
The Import menu will display a list of all binary file types stored on the Micro SD card.
Only binary files can be imported to the EPOCH 600
To Import a file:
Select Manage > Import
Choose the desired file and press [NEXT GROUP]
Press [P1] to create a name for the imported file
NOTE: The imported file cannot have the same name as a file already stored on the instrument
Press [NEXT GROUP], then [P1]

98. File Operations- Import/Export Summary
The chart below summarizes the different files types for Export/Import on the EPOCH 600:
Export File Type
Includes Parameter Data?
Includes Waveform Data?
Importable to other EPOCH 600 units?
Binary
Yes
CSV No
Screen shots captured using [2nd F], [F1]
Viewable in Excel only
XML
Viewable in External Software

99. File Operations- XML File Export Setup
To utilize the XML file export function, the user MUST perform a one-time setup step to import a XML Schema file from the microSD card to the instrument
This file allows the instrument to properly format the XML output
To import this XML Schema file:
Save the file E600Schema_101.xml to the microSD card
Install the card and turn the instrument ON
Navigate to the Instr Setup menu and select P5 (Misc)
Highlight “Copy XML Schema File from External SD Card”
Press P1 (Start) to load the file
For more information XML file formatting, contact the flaw detector group

100. Expanded Datalogger Option
The onboard datalogger can be enhanced to feature full corrosion style file types through the Expanded Datalogger Option.
P/N: EP600-XDATA (U )
This option includes the following data file types:
Sequential
Sequential + custom point
2D Grid
2D Grid + custom point
For more detailed information on the above file types, refer to the EPOCH 600 user manual.
2D EPRI
3D Grid
Boiler

101. Expanded Datalogger Option – File Creation
Once activated, the Expanded Datalogger option allows the user to create additional file types other than the standard CAL and INC files.
To create an advanced file:
In the File > Create menu, select Advanced for the file type
Enter the File Name
Enter a Description, Inspector ID, and Location Note if desired
Select Setup and press [P1] Ok to enter the setup menu

102. Expanded Datalogger Option – File Setup
In the Create menu, select the desired advanced File Type. Available file types are listed above the P-keys.
The example below shows a 2D file setup.
Using the Next Group key, fill in the parameters displayed with the selected file type.
When finished, select one of the Create options listed above the P-keys.

103. SOFTWARE OPTIONS AND FEATURES

104. Software Feature
Dynamic DAC/TVG

105. Dynamic DAC/TVG
The EPOCH 600 includes DAC and TVG capabilities as a standard feature. The EPOCH 600 includes the following standard DAC/TVG modes:
ASME
ASME-3
JIS
Custom
20-80

106. Dynamic DAC/TVG Setup
The first step in setting up DAC/TVG is to calibrate the instrument for the intended material, inspection range and general sensitivity. This includes:
Appropriate Pulser and Receiver adjustments (filters, energy, square wave pulser, etc)
Calibration for probe delay (zero offset) and material velocity
Appropriate screen range selection
Gain adjustment to bring first reference echo to 80% full screen height

107. Dynamic DAC/TVG Setup
Properly Calibrated EPOCH 600

108. DAC/TVG Option Activation
To Activate the DAC/TVG Option:
In the DAC/TVG menu press [F1] DAC/TVG
Press [P7] to enter the Setup screen
Use the adjustment knob, arrow keys, or P-keys to select the desired DAC/TVG mode
Press the [ESC] key to return to the main screen

109. DAC/TVG Reference Correct
Reference Correction: While inspecting using DAC/TVG, it is common to digitally compare the height of a reflector to the height of the curve. It is also common to use scanning gain while inspecting for defects. Scanning gain increases the height of the echo without changing the level of the curve.
An echo compared to a curve (in % or dB) while using scanning gain will not yield a true digital comparison. Reference Correction automatically removes scanning gain from the digital comparison only to allow the inspector to scan with scanning gain while still making a correct digital comparison between the echo and the curve.
Use the REF CORRECT control box to turn Reference Correction ON or OFF

110. DAC/TVG Curve Type
ASME, ASME-3 and CUSTOM DAC/TVG Modes allow the operator to define the Curve Type for the DAC curve and Warning Level curves:
CURVE – Connects the acquired reference points with a curved line which interpolates the attenuation of sound between each reference reflector.
STRAIGHT – Connects the acquired reference points with straight line segments.

111. Acquiring DAC Points
Building a DAC curve on the EPOCH 600 is fast and accurate!
Capture the reference reflector
Press [P1] to Add this reflector as a DAC point
Move GATE1 to capture the next reference reflector
Repeat until curve is built
Press [P3] Done to finish
NOTE: This DAC point collection is used for all DAC types

112. DAC/TVG Adjustments
While building a DAC curve, the EPOCH 600 allows the operator to adjust signal height of each reference reflector using the AUTO-XX% feature.
Using AUTO-XX% to acquire each point increases the accuracy of the curve, especially in longer sound paths or attenuating materials.
The operator can access AUTO-XX% by pressing [2nd F] [GATES]

113. DAC/TVG Adjustments
While building a DAC curve, the operator can make adjustments to the following gage parameters:
RANGE
SCREEN DELAY
GAIN
ANGLE
PART THICKNESS
OUTER DIAMETER (CSC)
Live Range Adjustment

114. DAC/TVG Adjustments
While building a DAC curve, the operator can delete a point that is acquired incorrectly by pressing [P2] Delete.
Wrong Point Acquired
DELETE to Remove

115. DAC/TVG Inspection These adjustments include:
After building or recalling a DAC/TVG curve, inspection adjustments can be made using the different parameters in DAC/TVG menu on the EPOCH 600.
These adjustments include:
DAC GAIN
GAIN STEP
CURVE NO
VIEW

116. DAC/TVG Inspection
DAC Gain adjustment either raises or lowers the gain of both the echo and the curve.
Since DAC codes require that any indication be sized above 20% full screen height, the usable range of a basic DAC curve is often limited.
DAC Gain allows an operator to inspect indications that occur at longer sound paths in a material by simply adjusting the overall gain to bring the curve and indication higher than 20% FSH.
Previously, multiple DAC setups would have to be built and stored to inspect the full range of a test piece.
GAIN STEP defines the magnitude of the DAC GAIN adjustment

117. Invalid Inspection Area
DAC/TVG Inspection
Inspection with DAC at multiple depths/sound path distances:
DAC GAIN = 0.0 dB
DAC GAIN = dB
Valid Inspection
(Over 20% FSH)
Invalid Inspection Area
(Curve Under 20% FSH)
Valid Inspection
(Over 20% FSH)

118. Invalid Inspection Area
DAC/TVG Inspection
20-80 DAC mode also allows easy inspection with DAC at multiple depths/sound path distances:
ASME DAC View
20-80 DAC View
Invalid Inspection Area
(Curve Under 20% FSH)
Valid Inspection
(Over 20% FSH)

119. DAC/TVG Inspection
CURVE NO adjustment changes the warning curve which defines the digital comparison being made between an indication and the DAC/TVG setup.
Warning Curves allow inspectors to more accurately size indications that are relatively larger or smaller than the main DAC curve.
Typical warning curves are set at +/- 6.0dB from the main curve, as well as dB (ASME-3).
An echo below the main curve that exactly matches the height of a -6.0dB warning curve indicates a flaw ½ the size of the reference reflector.

120. DAC/TVG Inspection
VIEW adjustment toggles between the DAC curve view and TVG view.
TVG (Time Varied Gain) represents indications from the same sized reflector at varying depths within a material as a 80% FSH echoes by varying GAIN across the EPOCH 600’s screen range.
TVG allows faster flaw scanning by bringing potential defects to code-compliant sizing heights without constant adjustment of DAC GAIN.
VIEW adjustment allows dynamic switching from DAC to TVG based on a single DAC setup, providing the power of both methods to an operator without extensive setup time.

121. DAC/TVG Custom
Various inspection codes exist in different markets that prescribe the use of DAC and/or TVG for flaw sizing.
Within these codes, Warning Curve levels are often defined to meet the code’s sizing requirements. Examples are:
ASME – One DAC curve representing the reference reflector height
ASME-3 – Three DAC curves at Reference, -6.0dB and -14.0dB
JIS – Positive and Negative curves at every +/-3.0dB
– One DAC curve representing the reference reflector height
The EPOCH 600 features CUSTOM DAC/TVG Mode, which allows the operator to define up to 3 Warning Curves (in addition to the main Reference curve) from dB to +24.0dB from Reference.

122. Software Option
AWS D1.1/D1.5

123. AWS D1.1/D1.5
The EPOCH 600 includes AWS weld rating software as an optional feature. The EPOCH 600 AWS software is intended to assist weld inspectors performing AWS-compliant inspections.

124. AWS D1.1/D1.5
The AWS code provides inspectors with a method to classify discontinuities found in welds using ultrasonic inspection. This code uses the following formula to develop an indication rating for a reflector found during an inspection:
A – B – C = D
A = Discontinuity Indication Level (dB)
B = Reference Indication Level (dB)
C = Attenuation Factor: 2 x (soundpath in inches – 1 inch) (dB)
D = Indication Rating (dB)
An AWS D1.1 inspector must take the Indication Rating (D) that is calculated based on A, B, and C to an Ultrasonic Acceptance – Rejection Criteria table produced by the AWS in order to classify the severity of the discontinuity that has been located.

125. AWS Setup
The first step in using the AWS weld rating software is to calibrate the instrument for the intended material, inspection range and general sensitivity. This includes:
Appropriate Pulser and Receiver adjustments (filters, energy, square wave pulser, etc)
Verification of wedge characteristics, such as Beam Index Point and Refracted Angle
Calibration for probe delay (zero offset) and material velocity
Appropriate screen range selection
Sensitivity adjustment from reference

126. Properly Calibrated EPOCH 600
AWS Setup
Properly Calibrated EPOCH 600

127. AWS Option Activation To Activate the AWS D1.1/D1.5 Option:
In the DAC/TVG menu press [F3] AWS
Press [P7] to enter the Setup screen
Use the adjustment knob, arrow keys, or P-keys to turn the option On or Off
Press the [ESC] key to return to the main screen
Press [P3] and enter the value to be used for the Ref Level (50% FSH or higher)

128. AWS Setup
Once AWS is activated, the user must record the Reference Gain value.
Bring the sensitivity reflector from the calibration block to reference height
Note: This reference height is the value entered during setup and will appear as the AUTO-XX% value above [P6]
Use the [P1] key to record this gain value as Ref B (Reference Gain Indication Level)
Press [P1] to accept this gain value as Ref B
The EPOCH 600 will now automatically rate all gated echoes with a D value

129. Software Feature
DGS/AVG

130. DGS/AVG
The EPOCH 600 now offers on-board DGS/AVG capabilities as a standard feature. The DGS/AVG software features a comprehensive library of transducers from both Olympus NDT and competitors.

131. DGS/AVG Overview
DGS/AVG is a flaw sizing method that compares the height of a reflector to a curve which represents the expected height of a known defect size at various sound path lengths within a part. DGS/AVG is similar to the DAC flaw sizing method, but with notable differences:
Reference Curve(s) not built point by point using reference reflectors – instead, curve(s) based on DGS Diagrams which predict the echo response (and attenuation) of multiple reflector sizes over a particular sound path range in carbon steel.
DGS Diagram

132. DGS/AVG Overview
DGS Diagrams are specific to the transducer being used for inspection.
DGS Diagrams/Curves are based on attenuation in an “ideal” carbon steel. The operator must make attenuation adjustments based on the inspection material to accurately predict the true attenuation, especially in the “far field”
DGS/AVG Setup only requires ONE reference point to create the required sizing curve

133. DGS/AVG Setup
The first step in setting up DGS/AVG is to calibrate the instrument for the intended material, inspection range and general sensitivity. This includes:
Appropriate Pulser and Receiver adjustments (filters, energy, square wave pulser, etc)
Calibration for probe delay (zero offset) and material velocity
Appropriate screen range selection
Gain adjustment to bring reference echo to 80% full screen height

134. DGS/AVG Setup
Properly Calibrated EPOCH 600

135. DGS/AVG Option Activation
To Activate the DGS/AVG Option:
In the DAC/TVG menu press [F2] DGS/AVG
Press [P7] to enter the Setup screen
Use the [NEXT GROUP] key along with the adjustment knob, arrow keys, or P-keys to make adjustments in the DGS/AVG menu
Press the [ESC] key to return to the main screen

136. DGS/AVG Parameters
DGS/AVG setup includes up to 10 parameter selections/adjustments before the operator can begin inspections:
Probe Type – The operator must select the type of probe used in the inspection (either Straight Beam, Angle Beam, Dual Probe, or Custom)
Probe Name – The operator must indicate exactly which probe is to be used in the inspection (DGS curves are based partially on the response of a specific probe in steel)
Reflector Type – A single reference reflection is required to build the DGS curve(s) on the EPOCH 600 – this can be from a Backwall, Flat-Bottom Hole (FBH), Side-Drilled Hole (SDH), K1/IIW Block Radius*, or K2/DSC Block Radius*
*used only with Angle Beam probe

137. DGS/AVG Parameters
Reflector Diameter – When a Reflector Type of SDH or FBH is selected, the operator must indicate the size of the reference hole.
Delta VT – Also known as Transfer Correction, Delta VT is a calculated value the accounts for an overall attenuation difference between a reference/calibration block and the actual inspection piece (typically caused by surface conditions or subtle material variation)
Registration Level – The value of the “critical” reference reflector for the inspection. This defines the relative height of the DGS curve and the comparison to unknown flaw reflections for rejection/acceptance criteria.
Warning Levels – DGS/AVG allows for three Warning Curves in addition to the main DGS curve. These can be set from +6.0dB to -14.0dB below the main curve, or to 0.0dB to turn these curves off.

138. DGS/AVG Parameters
ACV Specimen – An attenuation compensation value for the inspection piece. This value is used to adjust the DGS curve, which is based on attenuation in an “ideal” or “perfect” carbon steel, to reflect accurate attenuation response in a “real-world” test piece. This is especially important for longer sound paths. The calculation for this attenuation adjustment is defined in the code EN 583 and other documents.
ACV Calibration Block – An attenuation compensation value for the calibration block. This value serves the same purpose as ACV Specimen, but is used when capturing a reference reflector from the calibration block.
X-Value – This parameter is only used with Angle Beam probes. This value is the distance from the Beam Index Point to the front of the angle beam probe/wedge. It is used to remove this wedge distance from the Surface Distance measurement and allows operators to locate a flaw on a test piece by measuring from the front of the transducer, instead of from the Beam Index Point, which can be less accurate or difficult during inspection.

139. *ACV Specimen/Cal Block have not been calculated
DGS/AVG Setup
Properly Adjusted DGS/AVG Parameters
*ACV Specimen/Cal Block have not been calculated

140. DGS/AVG Reference
Once the DGS/AVG parameters have been appropriately adjusted, the operator must capture the Reference Reflector to complete the DGS/AVG setup.
Capture the Reference Reflector with Gate1
Use AUTO-80% to bring the reflector to 80% FSH
Press [P1] Ref to capture the Reference Reflector and build the DGS/AVG curve
Press [P1] YES to save the reference value

141. DGS/AVG Reference
While acquiring the Reference Reflector, the operator can make adjustments to the following gage parameters:
RANGE
SCREEN DELAY
GAIN
ZERO OFFSET
ANGLE
PART THICKNESS
OUTER DIAMETER (CSC)
Live Range Adjustment

142. Completed EPOCH 600 DGS/AVG Curve

143. DGS/AVG Inspection These adjustments include:
After building or recalling a DGS/AVG curve, inspection adjustments can be made using the different parameters in DGS/AVG menu on the EPOCH 600.
These adjustments include:
Scanning Gain
DELTA VT
REG LEVEL
ACVSPEC
These adjustments (except scanning gain) are the same Transfer Correction, Registration Level and Attenuation Correction Value (Specimen) values initially set up in the DGS/AVG menu. All values can be changed during live inspection as needed.

144. DGS/AVG Inspection
After building or recalling a DGS/AVG curve, Warning Curve level adjustments can be made by entering the DGS/AVG Setup menu on the EPOCH 600.

145. DGS/AVG Inspection
During inspections, the operator can choose to view a variety of digital measurements based on the gated indication. Specific measurements for DGS/AVG are:
ERS – Displays the Equivalent Reflector Size (ERS) of the gated indication
% to Curve – Compares the height of the gated indication to the DGS/AVG curve in amplitude %
Overshoot – Compares the height of the gated indication to the DGS/AVG curve in gain (dB)

146. Custom DGS/AVG Probes
DGS/AVG allows the operator to import Custom DGS probes. The GageView Pro PC interface program must be used to create any Custom DGS Probe. Once created, the user can import this Custom Probe library via two methods:
Direct Import – Using GageView Pro, directly connect the EPOCH 600 to the PC and manage custom probes. See the GageView Pro (or higher) instructional PowerPoint for further information
File Import – Using GageView Pro, create a Custom DGS Probe library and save to a CustomProbe.BIN file. Then Import to the EPOCH 600 using the following steps:
Save the CustomProbe.BIN file to the microSD card
Insert into the EPOCH 600 and turn the unit ON
Navigate to the INST SETUP > Misc menu
Highlight the import function shown and press [P1] to Start the import

147. formerly Spotweld Overlay
Software Feature
Template Storage
formerly Spotweld Overlay
147

148. Template Storage
Template Storage, previously known as Spotweld Overlay, is an optional feature on the EPOCH Since the option is functional for applications other than spotweld inspection it has been given a more general name.

149. Template Storage- Overview
The Template Storage option allows the operator to store reference templates, or reference echoes similar to Peak Hold, in memory for comparison to the live A-Scan.
The operator can call up a reference template on the live screen at any time by pressing the corresponding P key.
This allows simple comparisons of known conditions to the live A-Scan to assist the operator.
Ordering Information: EP600-TEMPLATE (U )

150. Template Storage- Option Activation
To activate the Template Storage option:
In the DAC/TVG menu press [F5] Template
Press [P7] to enter the Setup screen
The option is turned ON and OFF using the control here.
The operator can specify if Gain adjustment should be active or not – in many spotweld applications this is restricted.
The list of template names is shown here.

151. Template Storage- Adding Templates
To add a template:
In the Template Name Edit field, press [P1] Edit to bring up the virtual keyboard
Enter the name of the desired template and press [P2] Add

152. Template Storage- Adding Templates
The list of templates is highly flexible, the user can create as many as required for the application.
The EPOCH 600 can store up to a maximum of 20 templates
The first five added templates are the primary templates that will appear above the P-Keys on the live screen.
Additional templates are accessible through a menu.
Move Up / Down: Moves the highlighted template Up / Down within the list.
Delete: Deletes the highlighted template.
Del All: Deletes all templates.

153. Template Storage- Editing Templates
To edit a template:
Select the desired template from the Template Names box
In the Template Name Edit field, press [P1] Edit to bring up the virtual keyboard
Edit the template name and press [P3] Replace

154. Template Storage Operation- Gain Adjustment
Gain adjustment is a NEW feature in Template Storage which allows for more flexibility outside of spotweld inspections
The GAIN On/Off function allows the user to choose whether live gain adjustment is possible while the Template Storage option is active.
Turning Gain Off disables base and scanning gain access during inspection, and ensure that every template in the current setup can be compared directly to the live A-scan at a common reference level.

155. Template Storage Operation- Gain Adjustment
Turning Gain On enables SCANNING gain access during inspection. When a template is saved, the BASE gain is also stored. If the operator recalls a template for comparison, the live A-scan is AUTOMATICALLY scaled to match the stored base gain. This forces a valid reference comparison.
Each template can have a different base gain.

156. Template Storage Option- Operation
On the live screen you will see that the Template Storage controls automatically appear above the P keys.
Some other parameters are still active. If you make an adjustment then the Template Storage controls will reappear after 5-10 seconds.

157. Template Storage Option- Operation
The first five templates are accessible using the [P1]-[P5] keys.
The others are accessible by pressing the [P6] key. See screenshots below:

158. Template Storage Option- Storing Templates
To store a template there are two methods:
For the first (5) templates: Press [2nd F] and the corresponding P-key
For all templates: Press [P6], highlight the template, press [P1] Store
Once a template has been stored, an “*” symbol will appear below the template name. In the Templates menu, the “*” will display to the right of the template
Saved Templates

159. Template Storage Option- Activating a Template
To activate/load a template:
For the first (5) templates: Press the corresponding P-key
For all templates: Press [P6], highlight the template, press [P2] Load
For the first (5) templates, once a template has been activated, an “-A-” symbol will appear below the template name
For the remaining templates, the currently active template will appear above [P6] in place of the Templates Menu.

160. Template Storage Option- Example
The following slides show an sample set of stored templates for a spotweld inspection:
Lower Left: GOOD template stored by pressing [2nd F], [P1].
Lower Right: WELD2 template stored by entering Template Storage menu, highlighting WELD2, and pressing [P1].

161. Template Storage Option- Example
To display a template you just press the corresponding P-Key or go to the Template Storage menu, highlight the desired template, and press [P2] to Load it to the live screen.
The live A-Scan can be displayed with the template for comparison as in the screenshot on the lower right.

162. Template Storage Option
Additional Information:
This option can be very useful for spotweld inspection and also for condition monitoring over time.
As all of UT testing is in some way a comparative test, Template Storage can be used in many different applications to compare known conditions to unknown samples.
Many users prefer to display the live A-Scan as filled in and the Template (or envelope) as hollow. This can be done in the Display Setup > Display Setup menu.
When you save an ID with Template Storage active the instrument will save all stored templates with each ID for review.

163. Software Option
API 5UE

164. API 5UE
The EPOCH 600 includes API 5UE crack sizing software as an optional feature. The EPOCH 600 API 5UE software is intended to aid operators using API Recommended Practice 5UE in the evaluation of crack height sizing during the pipe fabrication process.

165. API 5UE Overview
The API Recommended Practice 5UE was developed specifically for OCTG manufacturers to inspect and characterize inner-diameter (ID) cracking in newly fabricated pipe. The API 5UE code uses two crack sizing methods to characterize ID cracking: the Amplitude Comparison Technique (ACT) and the Amplitude-Distance Differential Technique (ADDT). The software developed for the EPOCH series aids in performing the ADDT method, which uses the following formula to determine ID crack size:
di = Amax*(T2-T1)*k
di = imperfection size
Amax = Maximum amplitude returned from defect area (usually 80%)
T1 = 6dB drop point from leading peak of Amax (distance or time)
T2 = 6dB drop point from trailing peak of Amax (distance or time)
k = a constant calculated from calibration to a reference notch
An inspector utilizing API 5UE must use the formula above to establish a crack height and refer to the API code for rejection or acceptance criteria.

166. API 5UE Setup
The first step in using the API 5UE crack sizing software is to calibrate the instrument for the intended material, inspection range and general sensitivity. This includes:
Appropriate Pulser and Receiver adjustments (filters, energy, square wave pulser, etc)
Verification of wedge characteristics, such as Beam Index Point and Refracted Angle
Calibration for probe delay (zero offset) and material velocity
Appropriate screen range selection
Sensitivity adjustment from reference

167. Properly Calibrated EPOCH 600
API 5UE Setup
Properly Calibrated EPOCH 600

168. API 5UE Option Activation
To Activate the API 5UE Option:
In the DAC/TVG menu press [F4] API5UE
Press [P7] to enter the Setup screen
Use the adjustment knob, arrow keys, or P-keys to turn the option ON
Press [NEXT GROUP] and use the knob or arrows to enter the known height of the calibration reference notch in the Ref. Depth box.
Press the [ESC] key to return to the main screen

169. API 5UE Setup- Peak Envelope
Once API 5UE is activated, the user must collect data from a reference notch to calibrate for inspections. This can be done using one of two methods:
Peak Envelope Method:
Press [PEAK MEM] activate Peak Memory
Find the reflection from the calibration notch and use AUTO-80% to bring this indication to 80% FSH
Adjust GATE1 so that it surrounds the indication
Move the transducer forward and backward over the notch to draw a peak envelope of the echo dynamics of the notch
Press [P1] to Collect the Amax, T1 and T2 data from the envelope
Press [F5] to move from calibration mode to Inspect mode

170. API 5UE Setup- Point by Point
Point by Point Method:
Find the reflection from the calibration notch and use AUTO-80% to bring this indication to 80% FSH
Adjust GATE1 so that it surrounds the indication
Press [P1] RefAMax to store the AMax point, and press [P1] to confirm
Move the transducer forward over the notch until the peak drops to 40% FSH
Press [P2] RefT1 to capture the T1 point

171. API 5UE Setup- Point by Point
Point by Point Method (cont.):
Move the transducer backward over the notch until the peak drops rises to 80% and then falls back to 40% FSH
Press [P3] RefT2 to capture the T2 point
Press the [P5] key to complete the calibration and move to Inspect mode
The operator can always us the [P6] key to Clear the current calibration points and start again

172. API 5UE Inspection
Once API 5UE is calibrated, the user can evaluate a live indication:
Find the reflection from an unknown crack height
Use either Peak Memory or the Point by Point method to collect values for Amax, T1 and T2 from the unknown indication
Note: The operator can size an unknown crack from the same reference gain level as used for calibration, OR by adjusting the peak to 80% FSH before collecting data points
Once the Amax, T1 and T2 data points are collected, the instrument shows the correct di indication height reading as a digital readout
Press [P6] to Clear the current collect points and continue inspecting
Press [P5] Re-Cal at any point to return to calibration mode

173. Software Option
Interface Gate
173

174. Interface Gate Applications
The Interface Gate (IF Gate) software option allows the EPOCH 600 to track the interface echo from a part that is being inspected using an immersion technique or captive water column transducer.
As a part with an irregular front surface moves past a transducer (or vice-versa) in an immersion tank, the water path between the transducer and part will vary.
The IF Gate tracks the echo from the front surface of the part as it moves and continuously positions it at the zero position on the display.
This stabilizes the signal on-screen and allows the operator to see the area of interest – the test piece – rather than the water path.
Ordering Information: EP600-IG (U )

175. IF Gate Application- Basic Example
This highly simplified example shows a part being inspected in an immersion tank.
The transducer sends sound through the water to the part being tested, producing an Interface Echo.
We position the IF Gate over this echo.
The sound travels through the part and reflects back producing a backwall echo.

176. IF Gate Application- Basic Example
Explanation:
We are not interested in the water path for flaw detection.
Once the IF Gate has been positioned over the Interface Echo, select GateIFSetup > GIF Run and turn ON
This will lock the Interface Echo to the zero position on the screen and allow the range to be expanded.

177. IF Gate Application- Flaw Detection Example
The EPOCH 600 is setup for flaw detection in this example.
IF Gate tracks the front surface
Gate 1 is the flaw gate
Gate 2 is the backwall monitor
IF Echo
Flaw
BW Echo
The most important measurements are 1-IF for flaw location and 1% for flaw sizing.
2-IF measures total part thickness and 2% measures backwall echo amplitude.
The IF TH measurement measures the water path.

178. Interface Gate Activation
Once the IF Gate option has been licensed, it can be turned ON by selecting GateIF > Status

179. Interface Gate Setup
The IF Gate can be set up using the GateIF Setup menu
You can enter a velocity for the IF Gate measurement using [P7]
This is typically the velocity of water for water path measurements
Once the IF Gate is turned on, Gate 1 will automatically be set up to track the IF Gate
Gate 2 tracking settings can be accessed in the Gate Setup, [F3] using the [P7] key.

180. Interface Gate Operation
Once the IF Gate has been turned on, it can be accessed from the live screen by pressing the GATES key.
Multiple presses of the GATES key will scroll through the Start, Width, and Level of all active gates. These values can then be adjusted in coarse or fine adjustment using the knob or the navigation pad.
G1Start
.216
G1Width
.741
G1Level
17%
G2Start
.989
G2Width
.568
G2Level
21%
GIFStart
.128
GIFWidth
.247
GIFLevel
30%

181. Interface Gate with TVG
Interface Gate on the EPOCH 600 is fully compatible with TVG
Common for true immersion inspection setups
IF Gate must be activated PRIOR to setting TVG
IF Gate can be in RUN or SETUP mode
TVG gain curve will track to IF Gate

182. Interface Gate with TVG- Setup
To activate TVG, IF Gate must already be turned on
Select DAC/TVG > DAC/TVG
Press [P7] Setup, and turn TVG Mode ON

183. Interface Gate with TVG- Operation
Press the ESCAPE key to return to the live screen
TVG Mode will automatically be in G1 Setup
Select [P5] G1Start to move the gate around the first reference reflector and adjust the gain to 80% FSH
Press [P2] to Add this point
Repeat for all reference reflectors to create a TVG Curve

184. Interface Gate with TVG- Operation
Once the TVG Curve is complete, press [P1] and set the TVG Mode to Inspection

185. Backwall Echo Attenuator
Software Option
Backwall Echo Attenuator
(BEA)

186. Backwall Echo Attenuation (BEA) Overview
The Backwall Echo Attenuation (BEA) option allows the operator to apply an independent gain level to the A-Scan after the Gate 2 start position.
BEA allows the operator to reduce the amplitude of the backwall echo when high gain levels are being used to find small flaws.
The high general gain setting makes internal reflectors easy to see and the BEA gain setting allows the operator to observe the peak of the backwall signal for variation.
Backwall variation could be the result of flaws that scatter sound energy or reflect sound energy away from the transducer.
Suppressing the backwall signal can also enhance detection of defects close to the backwall echo by allowing visibility of the defect and backwall peaks even when the two signals overlap at the baseline.

187. Backwall Echo Attenuation (BEA) Operation
The Backwall Echo Attenuation (BEA) option is activated using the Gate 2 status selection:
Gate 2 Status selections: Off, On, BEA
When BEA is selected, the BEA Gain control appears over [P6]
BEA Gain defaults to be equivalent to the current Base Gain

188. Backwall Echo Attenuation (BEA) Operation
When BEA is turned ON:
The operator may adjust the BEA gain independently to suppress the backwall echo.
Gate 2 Auto XX% may also be used to position the backwall at a reference level (i.e. 80%.)
Measurements and alarm conditions under Gate 2 are based on the attenuated echo.

189. Backwall Echo Attenuation (BEA) Example
A typical use of BEA is shown below:
Bring defect in Gate1 to 80%
Note that backwall echo signal is saturated

190. Backwall Echo Attenuation (BEA) Example
A typical use of BEA is shown below:
Turn BEA to ON

191. Backwall Echo Attenuation (BEA) Example
A typical use of BEA is shown below:
Use Gate2 AUTOXX% to decrease gain in Gate2 region to decrease backwall echo to 80%

192. Backwall Echo Attenuation (BEA) Notes
Important information regarding BEA is below. Please note that these comments may be different than the operation of other EPOCH instruments:
When BEA is activated, the Gate 2 start position can be adjusted anywhere on screen, even before Gate 1
When BEA is activated, the BEA gain region starts at the Gate 2 start position and ends at the Gate 2 end position
BEA must be positioned manually by the operator in all modes
BEA is not compatible with DAC, TVG or DGS
BEA is not compatible with the Interface Gate option

193. Questions or Comments?