AMB-110
10000V Insulation Resistance
Tester
Users Manual
• Mode d’emploi
• Bedienungshandbuch
• Manual d’Uso
• Manual de uso
AMB-110
10000V Insulation Resistance Tester
Users Manual
June 2011 , Rev.1
©2011 Amprobe Test Tools.
All rights reserved. Printed in China
English
Limited Warranty and Limitation of Liability
Your Amprobe product will be free from defects in material and workmanship for 1 year from the date of
purchase, unless local laws require otherwise. This warranty does not cover fuses, disposable batteries or
damage from accident, neglect, misuse, alteration, contamination, or abnormal conditions of operation or
handling. Resellers are not authorized to extend any other warranty on Amprobes behalf. To obtain service
during the warranty period, return the product with proof of purchase to an authorized Amprobe Test Tools
Service Center or to an Amprobe dealer or distributor. See Repair Section for details. THIS WARRANTY IS YOUR
ONLY REMEDY. ALL OTHER WARRANTIES - WHETHER EXPRESS, IMPLIED OR STAUTORY - INCLUDING IMPLIED
WARRANTIES OF FITNESS FOR A PARTICULAR PURPOSE OR MERCHANTABILITY, ARE HEREBY DISCLAIMED.
MANUFACTURER SHALL NOT BE LIABLE FOR ANY SPECIAL, INDIRECT, INCIDENTAL OR CONSEQUENTIAL
DAMAGES OR LOSSES, ARISING FROM ANY CAUSE OR THEORY. Since some states or countries do not allow
the exclusion or limitation of an implied warranty or of incidental or consequential damages, this limitation of
liability may not apply to you.
Repair
All test tools returned for warranty or non-warranty repair or for calibration should be accompanied by the
following: your name, company’s name, address, telephone number, and proof of purchase. Additionally,
please include a brief description of the problem or the service requested and include the test leads with the
meter. Non-warranty repair or replacement charges should be remitted in the form of a check, a money order,
credit card with expiration date, or a purchase order made payable to Amprobe® Test Tools.
In-Warranty Repairs and Replacement – All Countries
Please read the warranty statement and check your battery before requesting repair. During the
warranty period any defective test tool can be returned to your Amprobe® Test Tools distributor for an
exchange for the same or like product. Please check the “Where to Buy” section on www.amprobe.com
for a list of distributors near you. Additionally, in the United States and Canada In-Warranty repair and
replacement units can also be sent to a Amprobe® Test Tools Service Center (see address below).
Non-Warranty Repairs and Replacement – US and Canada
Non-warranty repairs in the United States and Canada should be sent to a Amprobe® Test Tools Service
Center. Call Amprobe® Test Tools or inquire at your point of purchase for current repair and replacement
rates.
In USA In Canada
Amprobe Test Tools Amprobe Test Tools
Everett, WA 98203 Mississauga, ON L4Z 1X9
Tel: 877-AMPROBE (267-7623) Tel: 905-890-7600
Non-Warranty Repairs and Replacement – Europe
European non-warranty units can be replaced by your Amprobe® Test Tools distributor for a nominalv
charge. Please check the “Where to Buy” section on www.amprobe.com for a list of distributors near
you.
European Correspondence Address*
Amprobe® Test Tools Europe
Beha-Amprobe GmbH
In den Engematten 14
79286 Glottertal, Germany
Tel.: +49 (0) 7684 8009 - 0
www.amprobe.eu
*(Correspondence only – no repair or replacement available from this address. European customers
please contact your distributor.)
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START/STOP key to start or stop any measurement.
ON/OFF key to switch the instrument ON or OFF.
MEM key to store, recall and erase results.
SELECT key to enter set-up mode for the selected function or to select the active parameter to be set.
cursor key to select an option upward.
cursor key to select an option downward.
cursor key to decrease the selected parameter.
cursor key to increase the selected parameter.
ESC key to exit the selected mode.
Light key to turn the display backlight ON or OFF.
Positive Insulation Resistance test terminal (+OUT)
GUARD test terminals intended to lead away potential leakage current while measuring the Insulation.
Sockets under points 12 and 13 are connected together inside the instrument.
Negative Insulation Resistance test terminal. (-OUT)
Screw (unscrew to replace the batteries).
Galvanic separated USB connector to connect the instrument to PC.
Distributor label or could be blank.
Galvanic separated RS 232 connector to connect the instrument to PC.
Mains connector to connect the instrument to the mains supply.
Serial number of the instrument.
AMB-110 10000V Insulation Resistance Tester
LCD
Display
Battery
cover
1 529 3 84671017
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AMB-110 10000V Insulation Resistance Tester
CONTENTS
SYMBOLS ..................................................................................................................................................3
SAFETY INFORMATION ............................................................................................................................3
MEANING OF SYMBOLS ...........................................................................................................................3
GENERAL PRECAUTIONS ..........................................................................................................................3
BATTERIES .................................................................................................................................................3
EXTERNAL VOLTAGES ..............................................................................................................................4
WORKING WITH THE INSTRUMENT ........................................................................................................4
HANDLING WITH CAPACITIVE LOADS ....................................................................................................4
UNPACKING AND INSPECTION ................................................................................................................4
FEATURES ..................................................................................................................................................5
OPERATION ...............................................................................................................................................6
Performing measurements ...................................................................................................................6
Autocalibration .....................................................................................................................................6
Mains powered instrument operation ................................................................................................7
Backlight operation (battery powered instrument) ...........................................................................7
Backlight operation (mains powered instrument) .............................................................................7
Off function ..........................................................................................................................................7
Configuration .......................................................................................................................................7
To clear all memory locations ..............................................................................................................8
MEASUREMENTS ......................................................................................................................................8
The purpose of insulation tests ...........................................................................................................8
DC vs. AC testing voltage .....................................................................................................................9
Typical insulation tests .........................................................................................................................9
Electrical representation of insulating material .................................................................................9
Basic Insulation resistance test .............................................................................................................10
Voltage dependence test – Step voltage test .....................................................................................10
POLARISATION INDEX ..............................................................................................................................11
DIELECTRIC DISCHARGE ...........................................................................................................................11
Withstanding voltage test ...................................................................................................................12
Humidity and insulation resistance measurements ............................................................................12
Guard terminal .....................................................................................................................................12
Filter options .........................................................................................................................................13
THE PURPOSE OF FILTERING ....................................................................................................................13
Example .................................................................................................................................................14
Voltage measurement ..........................................................................................................................14
Measurement procedure ......................................................................................................................14
Insulation Resistance measurement ....................................................................................................14
Measurement procedure ......................................................................................................................15
Setting up parameters for Insulation Resistance ................................................................................16
Enable/Disable the graph R(t) and Set-up the graph R(t) parameters in the Insulation Resistance function
..17
Diagnostic test ......................................................................................................................................18
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DIELECTRIC ABSORPTION RATIO (DAR) ..................................................................................................19
POLARIZATION INDEX (PI) .......................................................................................................................20
DIELECTRIC DISCHARGE TESTING (DD) ...................................................................................................20
Measurement procedure ......................................................................................................................20
Setting up the parameters of the Diagnostic Test ..............................................................................21
Enable/Disable the graph R(t) and Set-up the graph R(t) parameters in the Diagnostic Test function
...........22
Step Voltage Insulation Resistance testing .........................................................................................23
Measurement procedure ......................................................................................................................24
Setting up the parameters of the Diagnostic Test ..............................................................................25
Enable/Disable the graph R(t) and Set-up the graph R(t) parameters in the Step Voltage function
..............25
Withstanding voltage ...........................................................................................................................26
Measuring procedure: ..........................................................................................................................27
Setting up the parameters of the Diagnostic Test ..............................................................................27
WORKING WITH YOUR RESULTS .............................................................................................................28
Storing, Recalling and Clearing Results ...............................................................................................28
TRANSFERRING DATA TO A PC ................................................................................................................31
How to transfer the stored data ..........................................................................................................31
With the communication program, the following tasks can be performed .....................................31
TECHNICAL SPECIFICATIONS ....................................................................................................................31
GENERAL SPECIFICATIONS .......................................................................................................................35
Battery power supply 7.2 V DC (6 × 1.2V Ni-MH; IEC LR20) ...............................................................35
Environment Conditions ......................................................................................................................35
Autocalibration .....................................................................................................................................35
Connecting System ...............................................................................................................................35
Discharging ...........................................................................................................................................35
RS232 Serial Communication ...............................................................................................................35
Usb Communication .............................................................................................................................35
Clock ......................................................................................................................................................35
MAINTENANCE .........................................................................................................................................36
Inserting and charging batteries for the first time ............................................................................36
Replacing and charging batteries ........................................................................................................36
Cleaning ................................................................................................................................................37
Calibration ............................................................................................................................................37
AMB-55 AND AMB-110 PC SOFTWARE INSTRUCTION MANUAL ..........................................................38
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SYMBOLS
Refer to the explanation in this
Manual Double Insulated or Reinforced
insulation
Risk of electric shock Earth Ground
Alternating Current Fuse
Direct Current Complies with EU directives
Do not dispose of this product as
unsorted municipal waste Conform to relevant Australian
standards
SAFETY INFORMATION
WARNING!
In order to reach the highest level of operator’s safety while carrying out various
measurements and tests using this Tester, as well as to ensure that the test equipment remains
undamaged, it is necessary to consider the following warnings:
MEANING OF SYMBOLS
Symbol on the instrument means “Read the User Manual with special care!”.
Symbol on the instrument means “Hazardous voltage higher than 1000 V may be present at
the test terminals!”.
GENERAL PRECAUTIONS
• If the test equipment is used in a manner not specied in this Users Manual, the protection
provided by the equipment may be impaired!
• Do not use the instrument and accessories, if any damage is noticed!
• Consider all generally known precautions in order to avoid the risk of electric shock while
dealing with electric installations!
• Service intervention or recalibration procedure can be carried out only by a competent and
authorized person!
• Only adequately trained and competent persons may operate the instrument.
• A dot matrix LCD offers easy-to-read results and all associated parameters. Operation is simple
and clear; the operator does not need any special training (except reading and understanding
this Users Manual) to operate the instrument.
BATTERIES
• Disconnect all test leads, main supply cable and switch the power off before opening the
Battery cover!
• Use only Ni-MH rechargeable batteries (IEC LR20)!
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EXTERNAL VOLTAGES
• Do not connect the instrument to a mains voltage different from the one dened on the label
adjacent to the mains connector, otherwise the instrument may be damaged.
• Do not connect test terminals to an external voltage higher than 600 V DC or AC (CAT IV
environment) to prevent any damage to the test instrument!
WORKING WITH THE INSTRUMENT
• Use only standard or optional test accessories supplied by your distributor!
This product is intended to be used to measure installations in process plants, industrial
installations, and residential applications.
• Equipment under test must be switched off (i.e. de-energized) before test leads are connected
to the equipment.
• Do not touch any conductive parts of equipment under test during the test.
• Make sure that the tested object is disconnected (mains voltage disconnected) before starting
the Insulation Resistance measurement!
• Do not touch the tested object whilst testing it, risk of electric shock!
• Before and after testing, conrm that no hazardous voltage presents at the terminals.
• In case of a capacitive test object (long tested cable etc.), automatic discharge of the object
may not be done immediately after finishing the measurement – “Please wait, discharging”
message will be displayed.
HANDLING WITH CAPACITIVE LOADS
• Note that 40 nF charged to 1 kV or 5 nF charged to 10 kV are hazardous live!
• Never touch the measured object during the testing until it is totally discharged.
• Maximum external voltage between any two leads is 600 V (CAT IV environment).
UNPACKING AND INSPECTION
Your shipping carton should include:
1 AMB-110 Meter
4 Test Leads
3 Aligator Clips (Red, Black, Green)
1 Power Supply Cord Set
1 Software CD
1 USB Cable
1 RS232 Cable
1 Users Manual
6 D Size Rechargeable Ni-MH batteries
If any of the items are damaged or missing, return the complete package to the place of purchase
for an exchange.
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FEATURES
This Tester is a portable battery / mains powered test instrument intended for the testing of
Insulation Resistance by using high test voltages of up to 10kV.
The instrument is designed and produced with the extensive knowledge and experience acquired
through many years of of working in this sector.
Available functions offered by this Tester:
• High insulation resistance measurement up to 10 T
- Programmable test voltage from 500 V up to 10 kV, step 25 V
- R(t) Graphs
- Programmable timer (1s up to 99 min)
- Automatic discharge of test object after completion of measurement
- Capacitance measurement
• Insulation resistance measurement versus test voltage (step-up voltage test)
- Five discrete test voltages proportionately set within preset test voltage range
- Programmable timer 1 min up to 99 min per step
• Polarization Index (PI), Dielectric Absorption ratio (DAR) and Dielectric Discharge (DD) ratio
- PI = RINS (t2) / RINS (t1)
- DAR = R1min / R15s
- DD = Idis1min / C.U
• Withstanding voltage (DC) up to 10 kV
- Programmable ramp test voltage from 500 V up to 10 kV
- High resolution ramp (approx. 25 V per step)
- Programmable threshold current up to 5 mA
• Voltage and frequency measurement up to 600 V AC/DC
A dot matrix LCD offers easy-to-read results and all associated parameters. The operation is
straightforward and clear to enable the user to operate the instrument without the need for
special training (except reading and understanding this Users Manual).
Test results can be stored on the instrument. The new professional PC software enables
straightforward transfer of test results and other parameters in both directions between the test
instrument and PC.
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OPERATION
Performing measurements
Switching on the instrument
Autocalibration
The instrument is switched ON by pressing the ON/OFF key. After turning on, the instrument will
execute the autocalibration (Fig. 2).
Note:
If batteries are defective or missing and the instrument is powered from mains supply, the
instrument will not turn ON.
Measuring test leads should be disconnected during auto-calibration. If not, the auto-
calibration procedure could be false and instrument will require disconnection of the test leads
and repeat switching OFF and ON.
After finishing the auto-calibration, the MAIN MENU (Fig. 3) will appear and instrument is
ready for normal operation.
Auto-calibration prevents the reduction in accuracy when measuring very low currents. It
compensates the effects caused by ageing, temperature and humidity changes etc.
A new auto-calibration is recommended when the temperature changes by more than 5 °C.
Fig. 1 First introduction Fig. 2 Auto-calibration
state
Fig. 3 Main Menu
Note:
If the instrument detects an incorrect state during the auto-calibration, the following warning
message will be displayed:
ERROR
Test Leads Connected:
Disconnect And Switch On The Instrument Again
Conditions Out Of Range: Press Start To Continue
Possible reasons for out of range conditions are excessive humidity, excessively high
temperature, etc. In this case it is possible to perform measurements by pressing the START/
STOP button again but results could be out of technical specification.
AMB-110 10kV
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Mains powered instrument operation
If you connect instrument to the mains supply when instrument is turned OFF, internal charger will
begin to charge the batteries but instrument will remain turned OFF. In button left angle of LCD,
flashing battery indicator will appear to indicate that the batteries are charging.
Note:
If batteries are defective or missing, the charger will not work. In button left corner of LCD
screen only plug character will be appeared.
If the instrument is connected to the mains supply when the instrument is turn ON, the
instrument will automatically switch from the battery supply to the main supply. In button
left corner of the LCD screen, the plug character will appear. If instrument is not in measuring
mode*, the internal charger will begin to charge the batteries. In button left corner of LCD
screen battery indicator will start to flash, indicating that the batteries are charging.
Note:
It is not recommended to connect or disconnect the instrument to mains supply while the
instrument is in measuring mode*.
* measuring mode when the instrument is performing a test.
Backlight operation (battery powered instrument)
After turning the instrument ON the LCD backlight is automatically turned ON. It can be turned
OFF and ON by simply pressing the LIGHT key.
Backlight operation (mains powered instrument)
After turning the instrument ON the LCD backlight is automatically turned OFF. It can be turned
OFF and ON by simply clicking the LIGHT key.
Off function
The instrument can be switched OFF only by pressing the ON/OFF key. The auto-off function is not
available to allow long-term measurements to be performed.
Conguration
The configuration function enables the selection and adjustment of the parameters (Table 1.) that
are not directly involved in the measurement procedure (Fig. 4).
In the lower section of the display the power supply status is shown.
The following procedure must be carried out when adjusting some of the configuration
parameters:
1. Use and arrows to select parameter (line) to be adjusted.
2. Use and arrows to change the value of the selected parameter. If there are two or more
sub-parameters in one line (e.g. date and time) then use the SELECT key to skip to the next sub-
parameters and back.
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To clear all memory locations:
1. Select Configuration from the main menu
2. Highlight the Memory Clear option using and arrows.
3. Press the SELECT key, (“Press MEM to confirm!” message will be displayed).
4. Press the MEM key to clear all memory locations or ESC to cancel the activity.
Fig. 4 Configuration state
Parameter Value Note
Contrast 0%..100% Adjustment of the LCD contrast
Filter Fil1, Fil2, Fil3, Fil0 Selection of noise rejecting filter, see the description of
Filter Option
Time Set real time (hour: minute)
Date Set current date (day-month-year)
Com Port
RS 232 2400,RS 232 4800,
RS 232 9600,RS 232 19200,
USB 115000
Set communication mode and rate.
Memory clear Clear all memory locations
Initialization For internal factory and service maintenance only!
DIAG. Starting time 0%..90%
Adjustment of start of the timer in the DIAGNOSTIC
TEST functions, according to the nominal voltage
Unominal. See additional explanation in Diagnostic
test.
Table 1. Configuration parameters
MEASUREMENTS
Generally Information about High DC voltage testing
See page 4 WORKING WITH THE INSTRUMENT for safety warnings.
The purpose of insulation tests
Insulating materials are important parts of almost every electrical product. The material’s properties
depend not only on its compound characteristics but also on temperature, pollution, moisture,
ageing, electrical and mechanical stress, etc. Safety and operational reliability require the regular
maintenance and testing of the insulation material to ensure it is kept in good operational
condition. High voltage tests are used to test insulating materials.
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DC vs. AC testing voltage
Testing with a DC voltage is widely accepted as being useful as testing with AC and / or pulsed
voltages. DC voltages can be used for breakdown tests especially where high capacitive leakage
currents interfere with measurements using AC or pulsed voltages. DC is mostly used for insulation
resistance measurement tests. In this type of test, the voltage is defined by the appropriate product
application group. This voltage is lower than the voltage used in the withstanding voltage test so
the tests can be applied more frequently without stressing the test material.
Typical insulation tests
In general, insulation resistance tests consist of the following possible procedures:
• Simple insulation resistance measurement also called a spot test;
• Measurement of the relationship between voltage and insulation resistance;
• Measurement of the relationship between time and insulation resistance
• est of residual charge after the dielectric discharge.
The results of this test can indicate whether the replacement of the insulation system is required.
Typical examples of where testing insulation resistance and its diagnosis are recommended are
transformer and motor insulation systems, cables and other electrical equipment.
Electrical representation of insulating material
The Fig. 5 represents the equivalent electrical circuit of an insulating material.
Riso
Cpi
Rpi
Ciso
Riss1
Riss2
material
surface
Itest
+
-
Guard
Fig. 5
Riss1 and Riss2 - the surface resistivity (position of optional guard connection)
Riso – the actual insulation resistance of material
Ciso – capacitance of material
Cpi, Rpi - represents polarization effects.
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I
PI
I
Ciso
I
Riso
I
Riss
Itest
Fig. 6
The Fig. 6 shows typical currents for that circuit.
Itest = overall test current (Itest= IPI+ IRISO+ IRISS)
IPI = polarization absorption current
IRISO = actual insulation current
IRISS = surface leakage current
Some application examples for using Teraohm 10 kV
Basic Insulation resistance test
Virtually every standard concerning the safety of electrical equipment and installations requires the
performance of a basic insulation testing. When testing lower values (in the range of M), the basic
insulation resistance (Riso) usually dominates. The results are adequate and stabilize quickly.
It is important to remember the following:
• The voltage, time and limit are usually given in the appropriate standard or regulation.
• Measuring time should be set to 60 s or the minimum time required for the Insulation
capacitance Ciso to be charged up.
• Sometimes it is required to take ambient temperature into account and adjust the result for a
standard temperature of 40 °C.
• If surface leakage currents interfere with the measurements (see Riss above) use the guard
connection (see the description of Guard terminal). This becomes critical when measured
values are in the G range.
Voltage dependence test – Step voltage test
This test shows if the insulation under test has been electrically or mechanically stressed. In this
instance the quantity and size of insulation anomalies (e.g. cracks, local breakdowns, conductive
parts, etc). is increased and the overall breakdown voltage is reduced. Excessive humidity and
pollution have an important role especially in the case of mechanical stress.
• The test voltage steps are usually close to those required in the DC withstanding test.
• Sometimes it is recommended that the maximum voltage for this test should not be higher
than 60 % of the withstanding voltage.
If the results of successive tests show a reduction in the tested insulation resistance the insulation
should be replaced.
Time dependence test – Diagnostic test
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POLARISATION INDEX
The purpose of this diagnostic test is to evaluate the influence of the polarization part of insulation
(Rpi, Cpi).
After applying a high voltage to an insulator the electric dipoles distributed in the insulator
align themselves with the applied electrical field. This phenomenon is called polarization. As the
molecules polarize, a polarization (absorption) current lowers the overall insulation resistance of
the material.
The absorption current (IPI) typically collapses after a few minutes. If the overall resistance of the
material does not increase, this means that other currents (e.g. surface leakages) dominate the
overall insulation resistance.
• PI is dened as the ratio of the measured resistances in two time slots. The most typical ratio is
10 min value to 1 min value but this is not a rule.
• The test is typically performed at the same voltage as the insulation resistance test.
• If the one-minute insulation resistance is greater than 5000 M, then this measurement may
not be valid (new modern types of insulation).
• Oiled paper used in transformers or motors is a typical insulation material that requires this
test.
In general, insulators that are in good condition will show a “high” polarization index while
insulators that are damaged will not. Note that this rule is not always valid.
General applicable values:
PI value Tested material status
1 to 1.5 Not acceptable (older types)
2 to 4 (typically 3) Considered as good insulation (older types)
>4(very high insulation resistance) Modern type of (good) insulation systems
Example for minimum acceptable values for motor insulation (IEEE 43):
Class A =1.5, Class B = 2.0, Class F =2.0, Class H =2.0.
DIELECTRIC DISCHARGE
An additional effect of polarization is the recovered charge (from Cpi) after the regular discharging
of a completed test. This can also be a supplementary measurement for evaluation of the quality of
insulating material. This effect is generally found in insulating systems with large capacitance Ciso.
The polarisation effect (described in “Polarisation Index”) causes a capacitance to form (Cpi). Ideally
this charge would dissipate immediately a voltage was removed from the material. In practice, this
is not the case.
In conjunction with the polarisation index (PI), Dialectic Discharge (DD) is another way to check
the quality and suitability of a insulation material. A material that discharges quickly would
provide a low value while a material that takes a long time to discharge will provide a higher value
(described in the table below, for more information see the section of Diagnostic test).
DD value Tested material status
> 4 bad
2 - 4 critical
< 2 good
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Withstanding voltage test
Some standards allow the use of a DC voltage as an alternative to AC withstanding voltage
testing. For this purpose the test voltage has to be present across the insulation under test for a
specific time. The insulation material only passes if there is no breakdown or flash over. Standards
recommend that the test starts with a low voltage and reaches the final test voltage with a slope
that keeps the charging current
under the limit of the current threshold. The test duration normally takes 1 min.
Withstanding voltage test or dielectric test is usually applied for:
• Type (acceptance) tests when a new product is being prepared for manufacture,
• Routine (production) tests for the verication of safety on each product,
• Maintenance and after service tests for any equipment where the insulation system can be
exposed to degradation.
Some examples for DC withstanding test voltage values:
Standard (only sample values) Voltage
EN/IEC 61010-1 CAT II 300 V basic insulation 1970 V
EN/IEC 61010-1 CAT II 300 V double insulation 3150 V
IEC 60439-1 (clearance between live parts…), withstanding impulse voltage 4 kV, 500 m 4700 V
IEC 60598-1 2120 V
Humidity and insulation resistance measurements
When testing outside the reference ambient conditions, the quality of the insulation resistance
measurements can be affected by humidity. Humidity adds leakage paths onto the surface of the
complete measuring system, (i.e. the insulator under test, the test leads, the measuring instrument
etc). The influence of humidity reduces accuracy especially when testing very high resistances. The
worst conditions arise in environments containing high condensation, which can also reduce safety.
In the case of high humidity, it is recommended to ventilate the test areas before and during the
measurements. In the case of condensed humidity the measuring system must dry and it can take
several hours or even few days to recover.
Guard terminal
The purpose of the GUARD terminal is to lead away potential leakage currents (e.g. surface
currents), which are not a result of the measured insulation material itself but are a result of
the surface contamination and moisture. This current interferes with the measurement i.e.
the Insulation Resistance result is influenced by this current. The GUARD terminal is internally
connected to the same potential as the negative test terminal (black one). The GUARDs test clip
should be connected to the test object so as to collect most of the unwanted leakage current, see
the figure Fig. 7 below.
Fig. 7 Connection of GUARD terminal to measured object
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where:
Ut ........... Test voltage
IL ............ Leakage current (resulted by surface dirt and moisture)
IM ........... Material current (resulted by material conditions)
IA............ A-meter current
• Result without using GUARD terminal: RINS = Ut / IA = Ut / (IM + IL) …incorrect result.
• Result using GUARD terminal: RINS = Ut / IA = Ut / IM ……correct result.
• It is recommended to use the GUARD connection when high insulation resistance (>10G )
are measured.
Note:
• The guard terminal is protected by an internal impedance (400 K).
• The instrument has two guard terminals to allow easy connection of shielded measuring
leads.
Filter options
Filters are built in to reduce the influence of noise on measurement results. This option enables
more stable results especially when dealing with high Insulation Resistances (Insulation Resistance,
Diagnostic Test, Step Voltage). In these functions, the status of the filter option is shown in the
top right corner of the LCD screen. The Table 2. below contains a definition of the individual filter
options:
Filter option Meaning
Fil0 Low pass filter with cut off frequency of 0.5 Hz in signal line.
Fil1 Additional low pass filter with cut off frequency of 0.05 Hz in the signal line.
Fil2 Fil1 with increased integrating time (4 s).
Fil3 Fil2 with additional cyclic averaging of 5 results.
Table 2. Filter options
THE PURPOSE OF FILTERING
In simple terms the filters smooth the measured currents by means of averaging and bandwidth
reduction. There are various sources of disturbance:
• AC currents at the mains frequency and its harmonics, switching transients etc, cause
the results to become unstable. These currents are mostly cross talk through insulation
capacitances close to live systems,
• Other currents induced or coupled in the electromagnetic environment of the insulation
under test.
• Ripple current from internal high voltage regulator,
• Charging effects of high capacitive loads and / or long cables.
Voltage changes are relatively narrow on high resistance insulation, so the most important point is
to filter the measured current.
Note
Any of the selected filter options increases the settling time with Fil1 to 60 s, Fil2 to 70 s, and
Fil3 to 120 s.
• It is necessary to pay close attention to the selection of time intervals when using the lters.
• The recommended minimum measuring times when using lters are the settling times of the
selected filter option.
14
Example:
• A noise current of 1 mA / 50 Hz adds approximately 15 % distribution to the measured result
when measuring 1 GOhm
• By selecting FIL1 option the distribution will reduce to less than 2 %.
• In general using FIL2 and FIL3 will further improve the noise reduction.
Voltage measurement
Selecting this function displays the following states (initial state and state with results after
completion of the measurement, see the Fig. 8).
Fig. 8 Voltage function display states
Measurement procedure:
• Connect the test leads to the instrument and to the measured source.
• Press the START key to start the measurement, continuous measurement starts to run.
• Press the START key again to stop the measurement.
• The result (see the right gure in the Fig. 8) can optionally be saved by pressing the MEM key
twice, see chapter the description of Store, Recall and Clear Operation.
Warning!
• Refer to Warnings chapter for safety precautions!
Insulation Resistance measurement
Selecting this function displays the following states (initial state and state with results after the
completion of the measurement). The Fig. 9 shows states when Graph R(t) is disabled.
Initial display Display with results
Fig. 9 Insulation Resistance function display states - Graph R(t) disabled
15
The Fig. 10 shows states when Graph R(t) is enabled. After taking a measurement, you can switch
back and forth between numerical mode display and graphical mode display by pressing or keys.
graphical mode
numerical mode
Note
• It is not possible to switching mode of presentation when measurement running!!!
Initial display -
numerical mode
Initial display -
graphical mode
Display with results -
numerical mode
Display with results -
graphical mode
Fig. 10 Insulation Resistance function display states - Graph R(t) enabled
Measurement procedure:
• Connect the test leads to the instrument and to the test object.
• Select INSULATION RESISTANCE function in MAIN MENU.
• Press the START/STOP key and release it, continuous measurement will begin.
• Wait until the test result has stabilized then press the START/STOP key again to stop the
measurement or, if enabled, wait for the set timer runs out.
• Wait for the object under test to discharge.
• The result can optionally be saved pressing the MEM key twice, see the description of Store,
Recall and Clear Operation.
16
Displayed symbols:
INSULATION RESISTANCE Name of selected function
Off fil0 (Fil1, Fil2, Fil3) Filter type enabled, see the section of Configuration
5000V Set test voltage
U=5323V Actual test voltage – measured value
I=266nA Actual test current – measured value
19.9GInsulation Resistance – result
C=0.0nF Capacitance of measured object
tm:04min 26s Timer information – test duration
Bar Analogue representation of result
Rmax=20.1GMaximum value of result (only if timer is enabled)
Rmin=19.9GMinimum value of result (only if timer is enabled)
Note
• If the timer is disabled then OFF is displayed instead of the timer value.
• During a measurement, the timer information displays the time needed to the complete the
measurement (tr) while after the completion the test duration (tm) is displayed.
• A high-voltage warning symbol appears on the display during the measurement to warn the
operator of a potentially dangerous test voltage.
• Value of capacitance is measured during the nal discharge of the test object.
Setting up parameters for Insulation Resistance:
• Press the SELECT key, the set-up menu will appear on the display, see the Fig.11.
• Select the parameter (line) to be set using the and keys;
• Adjust set parameter using the and keys. Skip to the next sub-parameter by pressing the
SELECT key (if there are two or more sub-parameters) and repeat the adjustment.
• Complete the set-up adjustments by pressing either the ESC key or START/STOP key (to run the
measurement directly). The settings displayed last are stored.
Fig. 11 Set-up menu in Insulation
Resistance measurement
17
Displayed symbols:
INSULATION RESISTANCE Name of selected function
SETTING PARAMETERS:
Unominal 5000 V Set test voltage –25 V steps
Timer 5min 00s Duration of the measurement
Timer on/off ON ON: timer enabled, OFF: timer disabled
Time1 01min 00s Time to accept and display first Rmin and Rmax results
Graph R(t) ON Enable/Disable Graph R(t)
Timer and Time1 are independent timers. Maximum time for each of them is 30 min 60 s.
Enable/Disable the graph R(t) and Set-up the graph R(t) parameters in the Insulation Resistance
function:
• Press the SELECT key, Set-up menu appears on display, see the Fig. 12.
• Select the parameter Graph R(t) to be set using the and keys;
• Enable/Disable the graph R(t) using the and keys.
• Press the SELECT key to Set-up the parameters of the graph R(t), see the Fig. 13. Press the ESC
key to return to basic Set-up menu in the Insulation Resistance function.
• Complete the set-up adjustments pressing either the ESC key or START/STOP key (to run the
measurement directly). The last displayed settings are stored.
Fig. 12 Set-up menu in Insulation
Resistance measurement
Fig. 13 Set-up menu of the
Graph R(t)
Note
• If the Timer is OFF is not possible to Enable the Graph R(t).
• The time duration of Graph R(t) is equal to the value of Timer.
- The Timer value could be very long (up to 99 minutes), so the Special automatic decimation
algorithm is use to write the Graph R(t) to the LCD.
• The cursors of the Graph R(t) could be activated with key
• The cursors of the Graph R(t) could be moved with and keys.
Warning!
• Refer to Warnings chapter for safety precautions!
18
Diagnostic test
Selecting this function displays the following states (initial state and state with results after the
completion of the measurement). The Fig. 14 shows states when Graph R(t) is disabled.
Initial display – numerical mode Display with results – numerical mode
Fig. 14 Diagnostic test display states - Graph R(t) disabled
The Fig. 15 shows states when Graph R(t) is enabled. After taking a measurement, you can switch
back and forth between numerical mode display and graphical mode display by pressing or keys.
graphical mode
numerical mode
Note
• It is not possible to switching mode of presentation when measurement running!!!
Initial display -
numerical mode
Initial display -
graphical mode
Display with results -
numerical modeㄇ
Display with results -
graphical mode
Fig. 15 Diagnostic test display states - Graph R(t) enabled
Diagnostic test is a long duration test for evaluating the quality of the insulation material under
test. The results of this test enable the decision to be made on the preventive replacement of the
insulation material.
19
DIELECTRIC ABSORPTION RATIO (DAR)
DAR is ratio of Insulation Resistance values measured after 15s and after 1 minute. The DC test
voltage is present during the whole period of the test (also an Insulation Resistance measurement is
continually running). At the end, the DAR ratio is displayed:
Some applicable values:
DAR value Tested material status
< 1.25 Not acceptable
< 1.6 Considered as good insulation
> 1.6 Excellent
Note
• When determining Riso (15s) pay attention to the capacitance of the test object. It has to be
charged-up in the first time section (15s). Approximate maximum capacitance using:
where:
t .............. period of first time unit (e.g. 15s)
U ............ test voltage.
To avoid this problem, increase the DIAG. Starting time parameter in CONFIGURATION menu,
because start of timer in the DIAGNOSTIC TEST functions depends on the test voltage. The timer
begins to run when test voltage reaches the threshold voltage, which is product of the DIAG.
Starting time and nominal test voltage (Unominal).
Using filters (fil1, fil2, fil3) in the DAR function is not recommended!
Analysing the change in the measured insulation resistance over time and calculating the DAR and
PI are very useful maintenance tests of an insulating material.
POLARIZATION INDEX (PI)
PI is the ratio of Insulation Resistance values measured after 1 minute and after 10 minutes. The
DC test voltage is present during the whole period of the measurement (an Insulation Resistance
measurement is also running). On completion of the test the PI ratio is displayed:
20
Note
• When determining Riso (1min) pay close attention to the capacitance of the object under test.
It has to be charged-up in the first time section (1 min). Approximate maximum capacitance
using:
where:
t .............. period of first time unit (e.g. 1min)
U ............ test voltage.
To avoid this problem, increase the DIAG. Starting time parameter in CONFIGURATION menu,
because start of timer in the DIAGNOSTIC TEST functions depends on the test voltage. The timer
begins to run when test voltage reaches the threshold voltage, which is product of the DIAG.
Starting time and nominal test voltage (Unominal).
Analysing the change in the measured insulation resistance over time and calculating the DAR and
PI are very useful maintenance tests of an insulating material.
DIELECTRIC DISCHARGE TESTING (DD)
DD is the diagnostic insulation test carried out after the completion of the Insulation Resistance
measurement. Typically the insulation material is left connected to the test voltage for 10 to 30
min and then discharged before the DD test is carried out. After 1 minute a discharge current
is measured to detect the charge re-absorption of the insulation material. A high re-absorption
current indicates contaminated insulation (mainly based on moisture):
where:
Idis 1min .......... discharging current measured 1 min after regular discharge
U ...................... test voltage
C ...................... capacitance of test object.
Measurement procedure:
• Select DIAGNOSTIC TEST function in MAIN MENU.
• Connect the test leads to the instrument and to the measured object.
• Press the START/STOP key to start the measurement.
• Wait until set timer runs out, the result is displayed.
• Wait until the object under test has discharged
• The result can optionally be saved by pressing the MEM key twice, see the section of Store,
Recall and Clear Operation.
21
Displayed symbols:
DIAGNOSTIC TEST Name of selected function
Fil0 (Fil1, Fil2, Fil3) Filter type enabled, see the section of Configuration
5000V Set test voltage – step 25 V
U=5295 Actual test voltage – measured value
I=55.6nA Actual test current – measured value
10.5GInsulation Resistance – result
C=2.1nf Capacitance of measured object
Tr:00min 15s Set timer value
Bar Analogue representation of Riso result
R15sec=10.6GResistance value measured after set time 1
R01min=10.5GResistance value measured after set time 2
R10min=10.5GResistance value measured after set time 3
DAR=1.67 DAR as ratio of R1min / R15s
PI=1.21 PI as ratio of R03/R02
DD=__ DD result
Note
• A high-voltage warning symbol appears on the display during the measurement to warn the
operator of a potentially dangerous test voltage.
• The value of the capacitance is measured during the nal discharge of the test object.
• If enabled, the instrument measures Dielectric Discharge (DD) when the capacitance is in the
range of 5 nF to 50 F.
Setting up the parameters of the Diagnostic Test:
• Press the SELECT key, (the Set-up menu appears on display,
see the Fig. 16).
• Select the parameter) to be set using the and keys;
• Adjust the parameter using the and keys.
• Complete the set-up adjustments by pressing either the
ESC key or START key (to run the measurement directly).
The settings displayed last are stored.
Displayed symbols:
DIAGNOSTIC TEST Name of selected function
SETTING PARAMETERS:
Unominal 5000 V Set test voltage – step 25 V
Time1 01min Time node to take R1min result
Time2 02min Time node to take R1min result and calculate DAR
Time3 03min Time node to take R3min result and calculate PI
Fig. 16 Set-up menu in
Diagnostic Test
22
DD on/off ON ON: DD enabled, OFF: DD disabled
Graph R(t) ON Enable/Disable Graph R(t)
Time1, Time2 and Time3 are timers with the same start point. The value of each presents the
duration from the start of the measurement. The maximum time is 99 min. The following Fig.17
shows the timer relationships.
0 Time1 Time2 Time3 t
Start
R15s R01min
DAR
R03min
PI
Stop
(if enabled DD)
Time1 Time2
Time2 Time3
Enable/Disable the graph R(t) and Set-up the graph R(t) parameters in the Diagnostic Test function:
• Press the SELECT key, Set-up menu appears on display, see the Fig. 18.
• Select the parameter Graph R(t) to be set using the and keys;
• Enable/Disable the graph R(t) using the and keys.
• Press the SELECT key to Set-up the parameters of the graph R(t), see the Fig. 19. Press the ESC
key to return to basic Set-up menu in the Diagnostic Test function.
• Complete the set-up adjustments pressing either the ESC key or START/STOP key (to run the
measurement directly). The last displayed settings are stored.
Fig. 18 Set-up menu in
Diagnostic Test measurement
Fig. 19 Set-up menu of the
Graph R(t)
Note
• The time duration of Graph R(t) is equal to the value of Timer 3.
• The Timer value could be very long (up to 99 minutes), so the Special automatic decimation
algorithm is use to write the Graph R(t) to the LCD.
• The cursors of the Graph R(t) could be activated with key
• The cursors of the Graph R(t) could be moved with and keys.
Warning!
• Refer to Warnings chapter for safety precautions!
23
Step Voltage Insulation Resistance testing
Selecting this function displays the following states (initial state and state with results after the
completion of the measurement). The Fig. 20 shows states when Graph R(t) is disabled.
Initial display Display with results
Fig. 20 Step Voltage function display states - Graph R(t) enabled
The Fig.21 shows states when Graph R(t) is enabled. When Graph R(t) is enabled you can simple
switching initial state and state with results after the completion of the measurement, between
numericaland graphical mode with pressing or keys.
graphical mode
numerical mode
Note
• It is not possible to switching mode of presentation when measurement running!!!
Initial display -
numerical mode
Initial display -
graphical mode
Display with results -
numerical mode
Display with results -
graphical mode
g
Fig. 21 Step Voltage function display states - Graph R(t) enabled
24
In this test, the insulation is measured in five equal time periods with test voltages from one fifth
of the final test voltage up to full voltage (see the Fig. 22). This function illustrates the relationship
of a materials Insulation resistance and its applied voltage.
Measurement procedure:
• Connect the test leads to the instrument and to
the test object.
• Press the START/STOP key to start the
measurement.
• Wait until set timer runs out, (the result will be
displayed).
• Wait for the object under test to discharge.
• The results can be saved by pressing the MEM
key twice, see the section of Store, Recall and
Clear Operation.
Legend of displayed symbols:
STEP VOLTAGE Name of selected function
Fil0 (Fil1, Fil2, Fil3) Filter type enabled, see the section of Configuration
5000V Set test voltage – step 125 V
U=5308V Actual test voltage – measured value
I=266nA Actual test current – measured value
19.9GInsulation Resistance – result
C=1.2nF Capacitance of measured object
Tm:05min 00s Actual test duration
R1000V=20.0GLast result of 1st step
R2000V=20.0GLast result of 2nd step
R3000V=20.0GLast result of 3rd step
R4000V=19.9GLast result of 4th step
R5000V=19.9GLast result of 5th step
U1=1077V 1st step voltage
U2=2142V 2nd step voltage
U3=3239V 3rd step voltage
U4=4283V 4th step voltage
U5=5308V 5th step voltage
Note
• Timer information is displayed from the start of the measurement until the completion of
each step measurement.
• Timer information shows the complete measurement period after the completion of the
measurement.
0
0.2U
0.4U
0.6U
0.8U
U
U
T2T3T4T5Tt
Fig. 22 Step-up test voltage
25
• A high-voltage warning symbol appears on the display during the measurement to warn the
operator of a potentially dangerous test voltage.
• The value of capacitance is measured during the nal discharge of test object.
Setting up the parameters of the Diagnostic Test:
• Press the SELECT key, (the Set-up menu (Fig. 23) will appear
on the display);
• Select the parameter) to be set using the and keys;
• Adjust the parameter using the and keys.
• Complete the set-up adjustments by pressing either the ESC
key or START key (to run the measurement directly). The
settings displayed last are stored.
Displayed symbols:
STEP VOLTAGE Name of selected function
SETTING PARAMETERS:
Unominal 5000 V Set test voltage – step 1000 V
Step Time 01min Duration of measurement per step
Graph R(t) ON Enable/Disable Graph R(t)
Enable/Disable the graph R(t) and Set-up the graph R(t) parameters in the Step Voltage function:
• Press the SELECT key, Set-up menu appears on display, see the Fig. 24.
• Select the parameter Graph R(t) to be set using the and keys;
• Enable/Disable the graph R(t) using the and keys.
• Press the SELECT key to Set-up the parameters of the graph R(t), see the Fig. 25. Press the ESC
key to return to basic Set-up menu in the Step Voltage function.
• Complete the set-up adjustments pressing either the ESC key or START/STOP key (to run the
measurement directly). The last displayed settings are stored.
Fig. 24 Set-up menu in Step
Voltage measurement
Fig. 25 Set-up menu of the
Graph R(t)
Note
• The time duration of Graph R(t) is equal to the value of Step Time Multiplied by 5.
• The Timer value could be very long (up to 150 minutes), so the Special automatic decimation
algorithm is use to write the Graph R(t) to the LCD.
• The cursors of the Graph R(t) could be activated with key
• The cursors of the Graph R(t) could be moved with and keys.
Fig. 23 Set-up menu in Step
Voltage Test
26
Warning!
• Refer to Warnings chapter for safety precautions!
Withstanding voltage
This function offers Withstanding Voltage test of insulation material. It covers two types of tests:
a) Breakdown voltage testing of high voltage device, e.g. transient suppressors and
b) DC withstanding voltage test for insulation coordination purposes.
Both functions require breakdown current detection. The test voltage increases step by step
from the Start up to the Stop value over a predefined time and it is kept at the Stop value for a
predefined test time, see the figure below.
Both functions require breakdown current detection. In the function, the test voltage is increased
from the starting voltage to the stop voltage over a predefined time (set by the parameters). The
Stop voltage is then maintained for a predefined test time, (see the Fig. 26).
Ut Ut
Usto p
Ub
Usta rt Usta rt
U
step
00
T
step
T
end
tt
Fig. 26 Test voltage presentation without breakdown (left part) and with breakdown (right part)
Ut ........... Test voltage
Ustop ..... End test voltage
Ustep ..... Voltage step approx. 25 V (fixed value - not preset-able)
Ustart ..... Starting voltage
Tstep ...... Test voltage duration per step
Tend ....... Constant test voltage duration after reaching End value
t .............. Time
Ub .......... Breakdown voltage
Selecting this function displays the following states. The Fig. 27 shows the initial screen and a
screen with results after the completion of a measurement.
Initial display Display with results
Fig. 27 Withstanding Voltage function display states
27
Displayed symbols:
WITHSTANDING VOLTAGE DC Name of selected function
2000V Start test voltage
7000V Stop test voltage
7221V Actual test voltage – measured value
I=0.002mA Actual test current – measured value
tm:01min 00s Timer information
Measuring procedure:
• Connect the test leads to the instrument and to the measured object.
• Press the START/STOP key to start the measurement.
• Wait until the set timers run out or until breakdown occurs, (the result will be displayed).
• Wait for the object under test is discharge.
• The result can be saved by pressing the MEM key twice, see the section of Store, Recall and
Clear Operation.
Note:
• Breakdown is detected when the measured current reaches or exceeds the set current level
trigger.
Notes:
• The timer shows the time needed to complete each step during the measurement and it shows
the total measurement period after the completion of the measurement.
• A high-voltage warning symbol appears on the display during the measurement to warn the
operator of a potentially dangerous test voltage.
Displayed symbols:
WITHSTANDING VOLTAGE DC Name of selected function
SETTING PARAMETERS:
Ustart 2000V Start test voltage, step = 25 V
Ustop 7000V Stop test voltage, step = 25 V
Tstep 00min 00s Duration of test voltage per one step
Tend 01min 00s Duration of constant test voltage after reaching stop value
Itrigg 1.500mA Set trigger leakage current, step = 10 A
Setting up the parameters of Withstanding Voltage DC Test:
• Press the SELECT key, (the set-up menu (Fig. 28) appears on the display).
• Select the parameter) to be set using the and keys;
• Adjust the parameter using the and keys.
• Complete the set-up adjustments by pressing either the ESC key or START key (to run the
measurement directly). The settings displayed last are stored.
28
Fig. 28 Set-up menu in
Withstanding Voltage function
Tstep and Tend are independent timers. The maximum time for each timer is 99 minutes. Tend
begins after the completion of the ramp period. Ramp period can be calculated from:
Tramp Tstep.(Ustop – Ustart) / 25 V
If Tstep is set to 00min 00s, then the ramp voltage increases by approximately 25 V every 2s.
Warning!
• Refer to Warnings chapter for safety precautions!
WORKING WITH YOUR RESULTS
Storing, Recalling and Clearing Results
The instrument contains battery supported storage memory to retain results when power is
disconnected. This enables the test engineer to make the measurements and then to recall them
later on. This way the engineer can analyze and print results on the instrument or transfer them to
a computer for further analysis.
After pressing the MEM key, the memory menu (Fig. 29) is displayed. Here the engineer has the
option to save, recall and clear results
Fig. 29 Storage operation
menu
SAVE CLR RCL nnnn
The nnnn means ser. number of stored result.
• There are the following possibilities are selectable using the or arrow keys:
• To store result: Highlight SAVE and conrm by pressing the MEM key. If graph R(t) is enabled
in the measurement, it will be automatically saved with the measurement.
• To recall stored result: Highlight RCL and conrm by pressing the MEM key. The last stored
result will be displayed. The menu is replaced with:
29
Recall measurement without the graph R(t):
Recall: 0006
Recall measurement with the graph R(t):
Recall: 0007 G
“0006” and “0007” represents the serial number of the stored results. G letter means the
graph R(t), if added. Results can be scrolled through by using the and keys.
To see the Graph R(t) press the SELECT key, to go back to the numerical measurement result
press the ESC key.
• The recall function can be exited by pressing the ESC or Start key.
• To clear the last stored result: highlight CLR and conrm by pressing the MEM key.
To clear the complete memory see the paragraph of Configuration.
In addition to the main result also, the sub-results and parameters of the selected function are also
recorded. The following is a list of all the data stored for each function.
Function List of stored data
Voltage
Function name
Measured voltage
Frequency the measured voltage
Ser. number of stored result
Date *
Time *
Insulation resistance
Function name
Measured insulation resistance value
Set test voltage
Actual test voltage - measured value
Actual test current - measured value
Capacitance of the tested object
Duration of the measurement
Maximum detected value of measured resistance
Minimum detected value of measured resistance
Ser. number of stored result
Date *
Time *
30
Diagnostic test
Function name
Last measured insulation resistance
Set test voltage
Actual test voltage - measured value
Actual test current - measured value
Capacitance of the tested object
Duration of the complete test
Insulation Resistance value taken afterT1
Insulation Resistance value taken afterT2
Insulation Resistance value taken afterT3
DAR value
PI value
DD value
Ser. number of stored result
Date *
Time *
Withstanding voltage DC
Function name
Last measured test voltage
Set Start voltage
Set Stop voltage
Set trigger current value
Actual test current - measured value
Set Step test time
Set End time
Actual test time (at Stop test voltage)
Ser. number of stored result
Date *
Time *
Step voltage
Function name
Last measured insulation resistance
Set test voltage
Actual test voltage - measured value
Actual test current - measured value
Capacitance of the tested object
Complete duration of the measurement
First step measured resistance with its nominal voltage
First step actual test voltage - measured value
Second step measured resistance with its nominal voltage
Second step actual test voltage - measured value
Third step measured resistance with its nominal voltage
Third step actual test voltage - measured value
Fourth step measured resistance with its nominal voltage
Fourth step actual test voltage - measured value
Last step measured resistance with its nominal voltage
Last step actual test voltage - measured value
Ser. number of the stored result
Date *
Time *
31
Note
• *Date and time of storing the test result are transferred to PC while date and time of
recalling are displayed when recalling results.
TRANSFERRING DATA TO A PC
Stored results can be transferred to a PC. The communication program can identify the instrument
and download the data.
How to transfer the stored data:
• Connect the instrument to the COM port of the PC using the communication cable (RS232 or
USB).
• Power up both the PC and the instrument.
• In the CONFIGURATION menu of the instrument, set the communication mode (RS232 or USB)
and Baud Rate appropriately. At the end, leave the CONFIGURATION menu by pressing the
ESC button.
• Run the program on the PC. In the Conguration / Com Port menu, set the Com Port and
Baud Rate appropriately. The Auto Find function can be used to configure Com port Settings
automatically. If Auto Find function is not successful first time, try one more time.
• The PC and the instrument should automatically recognize each other.
With the communication program, the following tasks can be performed.
• download data;
• clear instrument data;
• change and download user data;
• prepare a simple report form;
• prepare a le to import into a spreadsheet program.
The program is compatible with Windows 2000/XP/VISTATM/Windows 7 operation systems.
TECHNICAL SPECIFICATIONS
Measurement specications
Note
All data regarding accuracy is given for nominal (reference) environment condition.
Insulation resistance
Nominal test voltage: Any within 500 and 10000 V
Current capability of test generator: >1 mA
Short-circuit test current: 5 mA 10 %
Automatic discharge of tested object: yes
32
Measuring range Riso: 0.12 Mup to 10 T*)
Display range Riso Resolution Accuracy
0 - 999 k1 k
(5 % of reading + 3 digits)
1.00 - 9.99 M10 k
10.0 - 99.9 M100 k
100 - 999 M1 M
1.00 - 9.99 G10 M
10.0 - 99.9 G100 M
100 - 999 G1 G
1.00 -10.00 T10 G (15 % of reading + 3 digits)
*Full-scale value of insulation resistance is defined according the following equation:
RFS = 1 G * Utest[V]
DC test voltage:
• Voltage value: Any value within 500 V and 10 kV, steps by 25 V.
• Accuracy: -0 / +10 % + 20 V.
• Output power: 10 W max.
Display range Test voltage (V) Resolution Accuracy
0 - 9999 V 1 V (3 % of reading + 3 V)
10 kV 0,1 kV (3 % of reading)
Current:
Display range I (mA) Resolution Accuracy
1.00 - 5.50 mA 10 A
(5 % of reading + 0.05 nA)
100 - 999 A 1 A
10.0 - 99.9 A 100 nA
1.00 - 9.99 A 10 nA
100 - 999 nA 1 nA
10.0 - 99.9 nA 0.1 nA
0.00 - 9.99 nA 0.01 nA
Noise current rejection (resistive load)
Filter option Maximum current @ 50Hz (mA r.m.s).
Fil0 1.5
Fil1 2.5
Fil2 4.5
Fil3 5
33
Generator Capability vs Resistance
0
2
4
6
8
10
12
0.1110 100
[ M ]
[ kV ]
Utest = 10kV Utest = 5kV
Electric absorption ratio DAR
Display range DAR Resolution Accuracy
0.01 - 9.99 0.01 (5% of reading + 2digits)
10.0 - 100.0 0.1 (5% of reading)
Polarization index PI
Display range PI Resolution Accuracy
0.01 - 9.99 0.01 (5 % of reading + 2 digits)
10.0 - 100.0 0.1 (5% of reading)
Dielectric discharge test DD
Display range DD Resolution Accuracy
0.01 - 9.99 0.01 (5 % of reading + 2 digits)
10.0 - 100.0 0.1 (5% of reading)
Capacitance range for DD test: 5 nF to 50 F.
Step voltage
• DC test voltage:
• Voltage value: Any value within 2000 V (400 V, 800 V, 1200 V, 1600 V, 2000 V) and 10 kV (2000
V, 4000 V, 6000 V, 8000 V, 10 kV), steps by 125 V.
• Accuracy: -0 / +10 % + 20 V.
Display range Test voltage (V) Resolution Accuracy
0 - 9999 V 1 V (3 % of reading + 3 V)
10 kV 0,1 kV (3 % of reading)
34
Withstanding voltage DC
• DC test voltage:
• Voltage value: Any value within 500V and 10kV.
• Accuracy: -0 / +10 % + 20 V.
Display range Test voltage (V) Resolution Accuracy
0 - 9999 V 1 V (3 % of reading + 3 V)
10 kV 0,1 kV (3 % of reading)
Leakage current
Display range Itrigg (mA) Resolution Accuracy
0.000 - 0.009 1 A (3 % of reading + 3 digits)
0.01 - 5,50 10 A (3 % of reading)
Voltage
Voltage AC or DC
Display range External Voltage (V) Resolution Accuracy
0 - 600 1 V (3 % of reading + 4 V)
Frequency of external voltage
Display range (Hz) Resolution Accuracy
0 and 45 - 65 0.1 Hz 0.2 Hz
Note
• for frequency between 0 and 45 Hz displayed <45 Hz
• for frequency over 65 Hz displayed >65 Hz
Input resistance: 3 M 10 %
Capacitance
Measuring range C: 50 F*
Display range C Resolution Accuracy
0.0 - 99.9 nF 0.1 nF
(5 % of reading + 2 digits)
100 - 999 nF 1 nF
1.00 - 50.00 F 10 nF
*Full-scale value of capacitance is defined according to the following equation:
CFS = 10 F * Utest[kV]
35
GENERAL SPECIFICATIONS
Battery power supply 7.2 V DC (6 × 1.2V Ni-MH; IEC LR20)
• Mains power supply : 90-260 V AC, 45-65 Hz, 60 VA / (300V CAT III)
• Protection classication : double insulation
• Over-voltage category : CAT IV 600 V
• Pollution degree : 2
• Degree of protection : IP 44 with case closed
• Dimensions (w × h × d) : 36 x 16 x 33 cm (14.2 x 6.3 x 13 in)
• Weight (without accessories, with batteries) : 5.5 kg (12.1 lb)
• Visual and sound warnings : yes
• Display : LCD dot matrix with backlight - (160 x 116)
• Memory : Non-volatile internal memory,1000 numerical measurements with time and date.
Environment Conditions
• Working temperature range : -10 to 50 °C (14° to 122°F)
• Nominal (reference) temperature range : 10 to 30 °C (50° to 86°F)
• Storage temperature range : -20 to +70 °C. (-4° to 158°F)
• Maximum humidity : 90% RH (0 to 40 °C / 32° to 104°F) non-condensing
• Nominal (reference) humidity range : 40 to 60 % RH
Autocalibration
• Auto-calibration of measuring system : every time after turning power on
Connecting System
• Two safety banana sockets : +OUT, -OUT (10kV CAT I, Basic)
• Two GUARD. banana sockets : GUARD (600V CAT IV, Double)
• Guard resistance : 400 k 10 %
Discharging
• Every time after measurement completion.
• Discharging resistance : 425 k 10 %
RS232 Serial Communication
• RS232 serial communication : galvanic separated
• Baud rates : 2400, 4800, 9600, 19200 baud, 1 stop bit,no parity.
• Connector : standard RS232 9-pin D female.
USB Communication
• USB slave communication : galvanic separated
• Baud rates : 115000 baud,
• Connector : standard USB connector - type B.
Clock
• Built-in Real time clock : Displayed permanently and stored as a parameter in combination
with the result.
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MAINTENANCE
Inserting and charging batteries for the rst time
Battery cells are stored in the bottom section of the instrument casing under the battery cover (see
Fig. 30). When inserting batteries for the first time please note the following:
• Disconnect any measurement accessories or mains supply cable connected to the instrument
before opening the battery cover to avoid electric shock.
• Remove the battery cover.
• Insert the batteries correctly (see Fig. 30), otherwise the test instrument will not operate!
• To easy insert the batteries to the battery holder rst insert the upper and the lower batteries
in each columns and at end the middle batteries.
• The battery cover has to be placed and xed back.
Connect the instrument to the mains power supply for 20 hours to fully charge batteries. (Typical
charging current is 600 mA).
When you charge the batteries for the first time, it normally takes about 3 charge and discharge
cycles for the batteries to regain full capacity.
Replacing and charging batteries
The instrument is designed to be power by rechargeable battery supported by mains supply. The
LCD contains an indication of battery condition (lower left section of LCD). When the low-battery
indication appears the batteries have to be recharged, connect the instrument to the mains power
supply for 20 hours to recharge cells. The typical charging current is 600 mA.
Note
• The operator does not need to disconnect the instrument from mains supply after the full
recharging period. The instrument can be connected permanently.
Fully charged rechargeable batteries can supply the instrument for approx. 4 hours. (Continues
testing at 10kV)
If the batteries have been stored for a long time, it normally takes about 3 charge and discharge
cycles for the batteries to regain full capacity.
Battery cells are stored in the bottom section of the instrument casing under the battery cover (see
Fig. 30). In case the batteries become defective please note the following:
• Turn the power off and disconnect any measurement accessories or mains supply cable
connectedto the instrument before opening the battery cover to avoid electric shock.
• Remove the battery cover.
• All six cells have to be replaced and they have to be of the same type.
• To easy remove batteries from battery holder rst remove the middle batteries in each column
and then the others (see the Fig. 30).
• Insert the batteries correctly (see Fig. 30), otherwise the test instrument will not operate and
battery may be discharged!
• To easy insert batteries to battery holder rst insert the upper and the lower batteries in each
columns and at end the middle batteries.
• The battery cover has to be placed and xed back.
• The Instrument will only work when rechargeable batteries are inside the instrument
Nominal power supply voltage is 7.2 V DC. Use six NiMH cells with size equivalent to IEC LR20
(dimensions: diameter = 33 mm, height = 58 mm). See the Fig. 30 for correct polarity of the
batteries.
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Fig. 30 Correct polarity of inserted batteries
Ensure batteries are used and disposed of in accordance with Manufacturers guidelines and in
accordance with Local and National Authority guidelines!
Cleaning
Use a soft cloth, slightly moistened with soapy water or spirit to clean the surface of the instrument
and leave the instrument to dry totally before using it.
Notes
• Do not use liquids based on petrol or hydrocarbons!
• Do not spill cleaning liquid over the instrument!
Calibration
It is essential that all measurement instruments be regularly calibrated. For occasional daily use,
we recommend an annual calibration to be carried out. When the instrument is used continuously
every day, we recommend calibrating the instrument every six months.
38
AMB-55 AND AMB-110 PC SOFTWARE INSTRUCTION MANUAL
INSTALL AMBLINK PRO SOFTWARE
• Insert the provided CD disk into CD-ROM drive.
• Double-click “AMBLINK PRO XX.X.exe” (X can be 0 to 9 or blank, indicating the software version)
• The pop-up windows will guide you through the program setup process.
INTRODUCTION
AMBLink PRO program is a PC Software for AMB-55 and AMB-110 instruments. It is intended for downloading
data from the instrument to PC and review downloaded data as a table or graph. The functionality for
downloading is connected to the password, that is unique for instrument’s serial number. If the password is
added, the functionality is enabled.
It enables you to:
• Download Memorized Data,
• View Downloaded Data,
• View Graph Of Data,
• View Graph Data In Table Form,
• Print Pro Report,
• Print Graph,
• Print Table,
• Save Results For Later Purposes.
Main Screen
It is essential that all measurement instruments be regularly calibrated. For occasional daily use we recommend
an annual calibr
Openle
Exit
Download Data*1
Move Item*2
Show Table
Draw Graph
PRO report print preview
Note: *1 Download data is not possible if the instrument is in the RECALL MEMORY mode.
*2 Toggle between moving objects within same level or between different levels.
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Main Menu Command:
It is essential that all measurement instruments be regularly calibrated. For occasional daily use we recommend
an annual calibr
File command enables you to Open, Close and Save file, Header setup, PRO Report print preview, Show
Table, Draw Graph, Export data and Exit from the program.
Open: opens an existing file with tree structure window and settings window.
Close: closes opened file. Before closing, a confirmation is asked in case the data has not been saved yet
or the structure was changed.
Save: saves changes into the file.
Save As: saves new structure or downloaded data into file.
Header Setup: in this menu all that belongs to PRO report can be set or edited (Report header, Report
comments and Page footer). Instrument data in gray fields are imported automatically from the
instrument. The Print Header data are saved or printed out together with test results. A default Print
Header can be set, stored or loaded.
PRO report Print Preview: shows opened file (data in table) in Print preview form. From print preview
window you can set up printer and print PRO report by clicking on the appropriate icon.
Draw Graph: draws graph of selected measurement.
Show Table: shows specific points of graph measurement in table form.
Export: transfers opened data to text file with defined Export format to be read further by a spreadsheet
software like EXCEL.
Exit: terminates AMBLink PRO program. Before exiting, a confirmation for termination is asked.
• Instrument command enables you Download data from the instrument, send (for MI 3295) and receive
Instrument data of the instrument and select currently used model of the instrument.
Download: downloads memorized data from the instrument.
Instrument data: enables you to read instrument information (name, model, FW and HW ver.), firm data,
user data and serial number.
Model: enables you to select suitable instrument model. If the ‘Auto Find’ option is selected, the
program tries to identify a currently connected instrument and select suitable one.
Cong command enables you to configure COM-Port, select Language and set Password.
COMPort: enables you to select appropriate COM Port according to your computer configuration.
Language: enables you to select different program languages if there are more than one available.
Password: enables you to add or remove password for communication with AMB-55 and AMB-110
instruments. You can add more different passwords to use only one PCSW for communication with more
instruments. If the password is not added, the program can not communicate with the instrument.
• Window command enables you to arrange opened les in Cascade, Tile Horizontally and Tile Vertically and
Minimize currently selected.
Cascade: enables you to arrange currently opened files so they overlap.
Tile Horizontally: enables you to arrange currently opened files in priority horizontal way.
Tile Vertically: enables you to arrange currently opened files in priority vertical way.
Minimize: enables you to minimize currently active file.
Help command enables you to use Contents help. About command enables you to view version and basic
information about AMBLink PRO program.
40
USING PROGRAM
Structure Editor
Structure editor enables you to edit a structure and belonging measurements. You can delete items, change its
settings (name), move subitems (measurements) from one item to another (move toolbutton should be in up
position ) and move items up and down within its parent item (move toolbutton should be in down position
).
When you drag item over another, the frame of the item is colored red, green or blue. Green color is associate
with move toolbutton and blue color with toolbutton . Green and blue colors mean the item can be
accepted and the red color means the item is refused. Blue frame appears when dragged item is inside its parent.
All subitems of the dragged item are moved together with its parent.
You can move item from one file to another file under the same rules.
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Structure Editor
File presentation consists of structure tree and setting field on the left side and results table on the right side of
the screen.
Setting properties are connected to the selected item from the structure tree. It is possible to change Item name.
Results are connected to the selected item from the structure tree. They can be presented in three comprehension
modes: full, medium and low. Full presentation includes all available results and sub results for each
measurement, medium presentation includes measurements and basic results while low presentation is only list
of measurements. Results table can display all results under selected item or only results of the selected item,
depending on the SUB Item state.
42
Graph
Graph command enables you to Print and Close graph.
View command enables you Auto Range, Restore Range and Refresh Data.
Print: prints graph
Close: closes graph
Auto Range: sets maximal value of Resistance X axis to optimal value due to max. resistance value.
Restore Range: sets maximal value of Resistance X axis to original value.
Refresh: repaints complete image of graph.
Zoom function enables you to see graph details. Press left mouse button and select range with dragging mouse
right.
For zoom out graph press left mouse button and drag mouse left.
Status bar shows cursor values of the Resistance, Voltage and time.
43
Table
Table command enables you to Print and Close table.
Print: prints table.
Close: closes table.
Measurement table represents 12 points of measurement graph. Table data belongs to time 15sec, 30sec
and 1min to 10min time. If the data at specific time is not available, 5s plus or minus is taken into account.
Functionality is available for all different measuring functions, except for STEP VOLTAGE.
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Print Header (Header, Comment, Footer)
1. Report header appears at the beginning of the first page of PRO report. There are five fields to define:
• Operator (the person who performed tests),
• Test site (location where tests were performed),
• Instrument’s data (automatically imported from the instrument),
• Report created on (report creation date),
It is saved with test results and appears when the file is reopened. It can be saved as a default header and
then loaded again.
2. Report Comments appears at the end of the last measurement results on the last page of PRO report. It is
intended to write general comment (max 14 rows). Comment is not saved with test results.
3. Report Footer is a single-line text that appears at the bottom of each page of a PRO report. It is saved with
test results and appears when the file is reopened. It can be saved as default footer and then loaded again.
During printing, inserted texts can appear out of printable area. Be attentive and adjust the length of the text
with help of Preview function.
45
Report print preview
Report print preview form shows measured results in PRO REPORT form completed with Report header, Report
comments and Page footer. This is the form that will appear on the printed PRO report.
From print preview window you can set up printer and print PRO report by clicking on the appropriate icon
Export
Format of the text file is defined in the Export Format window that is shown automatically after selecting File /
Export from Main Menu command of Main Screen.