Dakota Ultrasonics ZX-5DL Operating Manual

OPERATION MANUAL

DAKOTA ULTRASONICS

ZZXX--55 DDLL

Data Logging

Ultrasonic Thickness Gauge

P/N P-304-0002 Rev 1.10, March 2019

CONTENTS

CHAPTER ONE INTRODUCTION ...................................................................... 1

DISCLAIMER ......................................................................................................................... 1

1.1

CHAPTER TWO KEYPAD, MENU, DISPLAY & CONNECTORS ..................... 2

2.1

ON/OFF/ENTER KEY… ..................................................................................................... 2

2.2

PRB 0 KEY… ....................................................................................................................... 2

2.3

CAL KEY…. ......................................................................................................................... 3

DATA KEY… ....................................................................................................................... 3

2.4

2.5

CLR KEY…. ......................................................................................................................... 3

2.6

+/- INCREMENT/DECREMENT KEY’S…. .................................................................................. 3

2.7

MATL KEY… ....................................................................................................................... 3

2.8

MENU KEY… ...................................................................................................................... 3

2.9

THE DISPLAY ....................................................................................................................... 5

THE TRANSDUCER .............................................................................................................. 6

2.10

2.11

TOP END CAP .................................................................................................................... 8

CHAPTER THREE PRINCIPALS OF ULTRASONIC MEASUREMENT ......... 10

3.1

TIME VERSUS THICKNESS RELATIONSHIP ............................................................................. 10

3.2

SUITABILITY OF MATERIALS ................................................................................................. 10

RANGE OF MEASUREMENT AND ACCURACY .......................................................................... 10

3.3

3.4

COUPLANT ......................................................................................................................... 10

3.5

TEMPERATURE ................................................................................................................... 11

3.6

MEASUREMENT MODES ...................................................................................................... 11

CHAPTER FOUR SELECTING THE MEASUREMENT MODE ....................... 13

4.1

WHICH MODE & TRANSDUCER DO I USE FOR MY APPLICATION? ............................................ 13

CHAPTER FIVE MAKING MEASUREMENTS ................................................. 15

5.1

PROBE ZERO ...................................................................................................................... 15

5.2

MATERIAL CALIBRATION ..................................................................................................... 17

CHAPTER SIX VELOCITY GAUGE ................................................................. 24

6.1

VELOCITY GAUGE (VX) ....................................................................................................... 24

CALIBRATION TO A KNOWN THICKNESS ................................................................................ 25

6.2

6.3

CALIBRATION TO A KNOWN VELOCITY .................................................................................. 26

CHAPTER SEVEN ADDITIONAL FEATURES ................................................ 28

7.1 GAIN ................................................................................................................................. 28

7.2

HIGH SPEED SCAN ............................................................................................................. 29

7.3

ALARM ............................................................................................................................... 30

DIFFERENTIAL .................................................................................................................... 31

7.4

7.5

UNITS ................................................................................................................................ 32

7.6

LITE ................................................................................................................................... 33

7.7

BEEP ................................................................................................................................. 34

7.8

ZERO ................................................................................................................................. 35

7.9

VELOCITY (VX) .................................................................................................................. 36

PROBE DIAMETER ............................................................................................................ 37

7.10

7.11

LOCK ............................................................................................................................... 38

7.12

FACTORY DEFAULTS ........................................................................................................ 39

CHAPTER EIGHT DATA STORAGE ............................................................... 41

8.1

INTRODUCTION .................................................................................................................. 41

OPENING A DATA FILE ........................................................................................................ 41

8.2

8.3

STORING A MEASUREMENT ................................................................................................ 42

8.4

CLEARING A FILE ............................................................................................................... 43

8.5

CLEAR ALL FILES ............................................................................................................... 44

CHAPTER NINE DATA TRANSFER & POWER OPTIONS ............................ 46

9.1

CONNECTIVITY ................................................................................................................... 46

9.2

LOCATING STORED FILES ................................................................................................... 46

9.3

COPYING/OPENING FILES ................................................................................................... 46

9.4

LINE POWER ...................................................................................................................... 47

APPENDIX A - VELOCITY TABLE .................................................................. 48

APPENDIX B- APPLICATION NOTES ........................................................... 50

CHAPTER ONE
INTRODUCTION

The Dakota Ultrasonics model ZX-5 DL is a basic dual element thickness gauge with

the ability to locate blind surface pitting and internal defects/flaws in materials. Based

on the same operating principles as SONAR, the ZX-5 DL is capable of measuring

the thickness of various materials with accuracy as high as  0.001 inches, or  0.01
millimeters. The principle advantage of ultrasonic measurement over traditional
methods is that ultrasonic measurements can be performed with access to only one
side of the material being measured.

Dakota Ultrasonics maintains a customer support resource in order to assist users
with questions or difficulties not covered in this manual. Customer support may be
reached at any of the following:

Dakota Ultrasonics Corporation

1500 Green Hills Road, #107

Scotts Valley, CA 95066

Tel: (831) 431-9722

Fax: (831) 431-9723

www.dakotaultrasonics.com

1.1 Disclaimer

Inherent in ultrasonic thickness measurement is the possibility that the instrument will
use the second rather than the first echo from the back surface of the material being
measured. This may result in a thickness reading that is TWICE what it should be.
Responsibility for proper use of the instrument and recognition of this phenomenon
rest solely with the user of the instrument. Other errors may occur from measuring
coated materials where the coating is insufficiently bonded to the material surface.
Irregular and inaccurate readings may result. Again, the user is responsible for
proper use and interpretation of the measurements acquired.

1

CHAPTER TWO
KEYPAD, MENU, DISPLAY & CONNECTORS

The Keypad

2.1 ON/OFF/ENTER Key

The ON/OFF/ENTER key powers the unit ON or OFF. Since the same key is also
used as an ENTER key, the gauge is powered off by pressing and holding down the
key until the unit powers off.

Once the gauge is initially powered on, this key will function as the ENTER key,
similar to a computer keyboard. This key will be used to select or set a menu option.

Note: Unit will automatically power off when idle for 5 minutes. All current settings
are automatically saved prior to powering off.

2.2 PRB 0 Key

The PRB 0 key is used to “zero” the ZX-5 DL in much the same way that a

mechanical micrometer is zeroed. If the gauge is not zeroed correctly, all of the
measurements that the gauge makes may be in error by some fixed value. Refer to
page 15 for a further explanation of this important feature.

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ZX-5 DL Ultrasonic Thickness Gauge

2.3 CAL Key

The CAL key is used to enter and exit the ZX-5 DL's calibration mode. This mode is
used to adjust the sound velocity value that the ZX-5 DL will use when calculating

thickness. The tool will either calculate the sound-velocity from a sample of the
material being measured, or allow a known velocity value to be entered directly. This
provides increased linearity between transducers. Refer to page 17 for an
explanation on the various calibration options.

2.4 DATA Key

The DATA key accesses the data logging section of the ZX-5 DL, which consists of

50 sequential (single column) files with 250 storage locations per file. Refer to page
41 for an explanation on the various calibration options.

2.5 CLR Key

The CLR key is used in conjunction with the data logging section to clear a single
stored memory location. Refer to page 41 for an explanation on the various
calibration options.

2.6 +/- Increment/Decrement Key’s

The +/- Keys are used to increment/decrement values, navigate menus, and select
menu options.

2.7 MATL Key

The MATL Key is used to select a common basic material type from a short list of 9
materials and 2 programmable custom materials for calibration. Refer to page 17 for
an explanation on selecting a basic material type.

2.8 MENU Key

The MENU key is used to access and set all of the additional features of the ZX-5 DL

that are not at the top level of the keypad with a dedicated key. The features and
setting are outlined in the table below:

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Menu Feature Items:

Gain Scan Alarm Diff Unit Lite Beep Zero VX Probe

VLOW On On On English On On Manual On .18 5

LOW Off Off Off Metric Off Off Auto Off .25 5

MED Options Options Options .25 7

HIGH Set Lo Set

Nominal

VHI Set Hi Med .50 5

High

Lo .5 0 3

Here’s a quick overview of navigating through the various features in MENU:

Navigating the Features in Menu

1) Press the key once to enter the sub menu items.

2) Press the keys to toggle through the features.

3) To enable or edit the status of any feature, press the key.

4) The edit icon will start blinking to indicate that the ZX-5 DL is currently in

EDIT mode.

5) Press the keys to toggle through the setting options.

6) Press the key to accept changes and return to the top level of

features, or the key at any time to abort changes and return the

measurement screen.

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ZX-5 DL Ultrasonic Thickness Gauge

2.9 The Display

The ZX-5 DL uses a custom glass LCD backlit low temperature display for use in a

variety of climate conditions. It contains graphic icons, as well as both 7 and 14
segment display areas. Let’s take a closer look and what all these things are telling
us:

Note: This display is used for multiple gauge models in the ZX & PZX series. As a
result, some of the icons and segments that are illuminated during boot up, may not
be applicable to your specific model, and will never be illuminated during operation.
The icons and segments that will be used with the ZX-5 DL are shown in the diagram
above.

A. Edit: This icon will be displayed, and blinking, to let a user know when they

are in an edit mode to change a value or setting.

B. Large 7 segment:

will be displayed in this area.

C. Measurement Modes:

5 DL operates exclusively in pulse-echo (P-E) mode only.

D. Stability/Repeatability Indicator:

thickness measurement as a reference for the validity of the measurement.

The ZX-5 DL takes multiple measurements per second, and when all the

vertical bars are illuminated, it’s a reference that the same thickness value is
reliably being measured multiple times per second.

E. Battery: Indicates the amount of battery life the ZX-5 DL has remaining.

F. Backlight :

When this icon is illuminated, it indicates the backlight is on.

The thickness measurement, velocity or alpha message

This icon indicates the measurement mode. The ZX-

This is used in conjunction with the

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G. Small 7 Segment: The material velocity, speed the sound wave travels

through a given medium/material, is displayed in this area, informing the user

what material the ZX-5 DL is currently calibrated too. This area is also used

for alpha messages in the menu and edit modes.

H. Units:

inform the user what measurement units are currently being displayed in the
small 7 segment area.

I. Small 14 Segment:

the default, with the options of VLOW, LOW, MED, HIGH, VHI (40dB to 52db
gain range with MED at 46dB).

J. Units: This combination of icons are illuminated in different sequences to

inform the user what measurement units are currently being displayed in the
large 7 segment area. The plus/minus icon is illuminated when the DIFF
(differential) feature is activated.

K. Small 14 Segment: The material type is displayed in this area. If it is set to a

value of one of the materials in our material list, it will be displayed in alpha
characters indicating the material type. Otherwise it will be set to CUST,
indicating custom material type.

L. Features: The icons illuminated in this row across the bottom of the LCD

display which features are currently enabled. For a complete list of the menu

features in the ZX-5 DL, Refer to page 3 for a list. The ZX-5 DL can be locked

once calibrated, to avoid accidently changing the calibration. When this icon is

illuminated, the ZX-5 DL is in lock mode. Refer to page 38 for an explanation
on locking the ZX-5 DL.

M. File/Loc: This area is exclusively for the data storage section of the ZX-5 DL.

The icons and segment fields represent the current file open, and the current
storage location in the file. Refer to page 41 for an explanation of the data

storage feature in the ZX-5 DL.

This combination of icons are illuminated in different sequences to

Displays the current gain setting of the ZX-5 DL. MED is

2.10 The Transducer

The Transducer is the “business end” of the ZX-5 DL. It transmits and receives
ultrasonic sound waves that the ZX-5 DL uses to calculate the thickness of the
material being measured. The transducer connects to the ZX-5 DL via the attached

cable, and two coaxial connectors. When using transducers manufactured by Dakota
Ultrasonics, the orientation of the dual coaxial connectors is not critical: either plug

may be fitted to either socket in the ZX-5 DL.

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ZX-5 DL Ultrasonic Thickness Gauge

The transducer must be used correctly in order for the ZX-5 DL to produce accurate,

reliable measurements. Below is a short description of the transducer, followed by
instructions for its use.

This is a bottom view of a typical transducer. The two semicircles of the wear face
are visible, as is the barrier separating them. One of the semicircles is responsible
for conducting ultrasonic sound into the material being measured, and the other
semicircle is responsible for conducting the echoed sound back into the transducer.
When the transducer is placed against the material being measured, it is the area
directly beneath the center of the wear face that is being measured.

This is a top view of a typical transducer. Press against the top with the thumb or
index finger to hold the transducer in place. Moderate pressure is sufficient, as it is
only necessary to keep the transducer stationary, and the wear face seated flat
against the surface of the material being measured.

Measuring

In order for the transducer to do its job, there must be no air gaps between the wear­face and the surface of the material being measured. This is accomplished with the
use of a "coupling" fluid, commonly called "couplant". This fluid serves to "couple", or
transfer, the ultrasonic sound waves from the transducer, into the material, and back
again. Before attempting to make a measurement, a small amount of couplant
should be applied to the surface of the material being measured. Typically, a single
droplet of couplant is sufficient.

After applying couplant, press the transducer (wear face down) firmly against the
area to be measured. The Stability Indicator should have six or seven bars

darkened, and a number should appear in the display. If the ZX-5 DL has been

properly "zeroed" (see page 15) and set to the correct sound velocity (see page 17),
the number in the display will indicate the actual thickness of the material directly
beneath the transducer.

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Dakota Ultrasonics

If the Stability Indicator has fewer than five bars darkened, or the numbers on the
display seem erratic, first check to make sure that there is an adequate film of
couplant beneath the transducer, and that the transducer is seated flat against the
material. If the condition persists, it may be necessary to select a different transducer
(size or frequency) for the material being measured. See page 13 for information on
transducer selection.

While the transducer is in contact with the material that is being measured, the ZX-5
DL will perform four measurements every second, updating its display as it does so.

When the transducer is removed from the surface, the display will hold the last
measurement made.

2.11 Top End Cap

The top end cap is where all connections are made to the ZX-5 DL. The diagram

above shows the layout and description of the connectors:

Transducer Connectors

Refer to Diagram: The transducer connectors and battery cover/probe zero disk are

located on the ZX-5 DL’s top end cap. The transducer connectors are of type Lemo

“00”.

Note: There is no polarity associated with connecting the transducer to the ZX-5 DL,
it can be plugged into the gauge in either direction.

Probe Zero Disk & Battery Cover

Refer to Diagram: The Battery cover is the large round disk shown in the diagram.

Note: This same disk is also used as a probe zero reference disk. Simply remove

the cover when replacing the batteries (2 AA cells). When performing a manual
probe zero function, simply place the transducer on disk making firm contact.
Important: Be sure the battery polarity is correct, which can be found on the back
label of the ZX-5 DL.

Note: Rechargeable batteries can be used, however they must be recharged outside
of the unit in a standalone battery charger.

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ZX-5 DL Ultrasonic Thickness Gauge

USB-C Connector

Refer to Diagram: The USB-C connector, located on the bottom end cap, is a mini

type C female connector. It is designed to connect directly from the ZX-5 DL to a
standard USB type A port on a PC. The cable supplied with the ZX-5 DL is a USB

type C to a USB type A (pt# N-003-0330). See page 46 for information on
connectivity.

Note: This connector is also used to upgrade the ZX-5 DL with the latest version of
firmware.

9

CHAPTER THREE
PRINCIPALS OF ULTRASONIC MEASUREMENT

3.1 Time versus thickness relationship

Ultrasonic thickness measurements depend on measuring the length of time it takes
for sound to travel through the material being tested. The ratio of the thickness
versus the time is known as the sound velocity. In order to make accurate
measurements, a sound velocity must be determined and entered into the
instrument.

The accuracy of a thickness measurement therefore depends on having a consistent
sound velocity. Some materials are not as consistent as others and accuracy will be
marginal. For example, some cast materials are very granular and porous and as a
result have inconsistent sound velocities.

While there are many different ultrasonic techniques to measure thickness, which will
be discussed below, all of them rely on using the sound velocity to convert from time
to thickness.

3.2 Suitability of materials

Ultrasonic thickness measurements rely on passing a sound wave through the
material being measured. Not all materials are good at transmitting sound.
Ultrasonic thickness measurement is practical in a wide variety of materials including
metals, plastics, and glass. Materials that are difficult include some cast materials,
concrete, wood, fiberglass, and some rubber.

3.3 Range of measurement and accuracy

The overall measurement capabilities, based on the wide variety of materials, is
determined by the consistency of the material being measured

The range of thickness that can be measured ultrasonically depends on the material
type and surface, as well as the technique being used and the type of transducer.
The range will vary depending on the type of material being measured.

Accuracy, is determined by how consistent the sound velocity is through the sound
path being measured, and is a function of the overall thickness of the material. For
example, the velocity in steel is typically within 0.5% while the velocity in cast iron
can vary by 4%.

3.4 Couplant

All ultrasonic applications require some medium to couple the sound from the
transducer to the test piece. Typically a high viscosity liquid is used as the medium.
The sound frequencies used in ultrasonic thickness measurement do not travel
through air efficiently. By using a liquid couplant between the transducer and test
piece the amount of ultrasound entering the test piece is much greater.

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ZX-5 DL Ultrasonic Thickness Gauge

3.5 Temperature

Temperature has an effect on sound velocity. The higher the temperature, the slower
sound travels in a material. High temperatures can also damage transducers and
present a problem for various liquid couplants.

Since the sound velocity varies with temperature it is important to calibrate at the
same temperature as the material being measured.

Normal temperature range

Most standard transducers will operate from 0F to 250F.

High temperature measurements

Special transducers and couplants are available for temperatures above 250F up to
1000F with intermittent contact. It is necessary to cool the transducer by
submerging it in water between measurements.

Modes and temperature errors

In addition to errors caused by velocity changing with temperature, some modes
(measurement techniques) are affected more than others. For example, dual
element pulse-echo mode has larger errors due to changes in the temperature of the
transducer. However, multi-echo techniques offer temperature compensation help to
minimize these errors.

3.6 Measurement Modes

This section will cover the different measurements modes of the ZX-5 DL, the

transducers required, and the reasons for using specific modes:

Pulse-Echo (P-E) Mode:

Pulse-echo mode measures from the initial pulse (sometimes referred to as an
artificial zero) to the first echo (reflection). In this mode, either an automatic or
manual zero can be performed depending on the zero probe setting. If the manual
mode has been selected, the transducer is placed on the reference disk located on

top of the ZX-5 DL, and the PRB 0 key pressed to establish a zero point for the

transducer connected. If the Auto Zero feature is enabled, simply pressing the PRB
0 key will perform an electronic zero to establish the same zero point.

In pulse-echo mode, errors can result from surface coatings and temperature
variations. Since pulse-echo only requires one reflection, it is the most sensitive
mode for measuring flaw/defects when measuring heavily corroded metals.

V-Path Correction

Dual element delay line transducers have two piezoelectric elements focused
towards one another at a slight angle, mounted on a delay line. One element is used
for transmitting sound, while the other element receives the sound reflection. The

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two elements and their delay lines are packaged in a single housing but acoustically
isolated from each other with an insulated sound barrier. This allows the transducer
the ability to achieve very high sensitivity for detecting small defects. Also, the
surface of the test material does not have to be as flat in order to obtain good
measurements.

Dual element transducers are normally used in pulse-echo mode for finding defects,
and in echo-echo mode for through coating measurements.

Dual element delay line transducers are have a usable range of 0.025” and up,
depending on the material, frequency, and diameter.

A limitation of dual element delay-line transducers is the V shaped sound path.
Because the sound travels from one element to another, the time versus thickness
relationship is non-linear. Therefore, a correction table in the instruments software is
used to compensate for this error.

Dual Element Transducer showing V-path of signal

Searching for small defects

Dual element delay line transducers are especially useful in searching for small
defects. In pulse-echo mode with high amplifier gain, very small defects can be
located. As a result, this configuration is commonly used for corrosion inspections.
The dual element style transducer will find wall deterioration, pits, cracks, and any
porosity pockets during tank and pipeline inspections.

12

CHAPTER FOUR
SELECTING THE MEASUREMENT MODE

4.1 Which mode & transducer do I use for my application?

High penetration plastics and castings

The most common mode for these types of applications is pulse-echo. Cast iron
applications require 1 - 5MHz frequencies, and cast aluminum requires a 7 - 10MHz
frequency depending on the thickness. Plastics typically require lower frequencies
depending on the thickness and make-up of the material as well. Larger diameters
offer greater penetration power based on the size of the crystal.

Corrosion & Pit Detection in steel and cast materials

Pulse-echo mode is commonly used for locating pits and defects. Typically a 5MHz
transducer, or higher, will be used for these types of applications. Use low
frequencies for greater penetration and use higher frequencies for better resolution.

Measuring Material & Coatings

The pulse-echo coating mode should be used when both material and coating
thickness are required, while still requiring the ability to detect flaws and pits. A
special coating style transducer is required for use in this mode. There are a variety
of coating transducers in various frequencies available from Dakota.

Thru Paint & Coatings

Often times, users will be faced with applications where the material will be coated
with paint or some other type of epoxy material. Since the velocity of the coating is
approximately 3 times slower than that of steel, pulse-echo mode will result in an
error if the coating or paint is not completely removed.

Thin materials

Pulse echo mode and a high frequency transducer is commonly used for these types
of applications. The most common transducers are the 7.5MHz and 10MHz models
with extra resolution. The higher frequencies provide greater resolution and a lower
minimum thickness rating overall.

High temperature

Special 5 MHz High temperature transducers are available for these types of
applications. Both pulse-echo and echo-echo modes will also work for these
applications. However, echo-echo mode will eliminate error caused by temperature
variations in the transducer.

13