eddyvisorsc v01 en

Manual

eddyvisorSC29 May 2008 (v 01e)

ibg Doc: 0713431e

Software and Manual

Copyright 2008 by ibg Prüfcomputer GmbH,Pretzfelder Str. 27, D-91320 Ebermannstadt

The copyright claimed covers all forms and types of materials and information fallingunder the copyright, which at the present time are legally admitted or granted in thefollowing, including material generated without restriction from the softwareprogramme appearing on the screen, such as symbols, screen displays and thelike.

Exclusion of responsibility

Great care was taken in compiling texts and figures. Nevertheless, errors cannot beruled out completely. Editors and authors cannot assume any legal responsibility orliability for erroneous information and resulting consequences. The editor will readilyaccept any proposals for improvement and hints at errors.

The unit delivered incorporates the latest state of the art. The manufacturer declinesany legal responsibility and liability for inspections carried out with the apparatusand for resulting consequences. Successful implementation of an inspectionpresupposes, in addition to the control of the unit setting, also a knowledge of theproduct to be tested, its material properties, of possible errors and their underlyingcauses. If these prerequisites are not satisfied, the result will be questionable. Inorder to avoid faulty operation and other errors, training in the manufacturer'sfactory or by an independent training organisation is recommended.

eddyvisor® is a registered trademark of ibg Prüfcomputer GmbH.

HP and LaserJet are registered trademarks of Hewlett-Packard Corporation.

Trademarks are used without warranting free usability.

ibg Headquarter:

ibg Prüfcomputer GmbHPretzfelder Straße 27D-91320 EbermannstadtTel: +49-9194-7384-0Fax: +49-9194-7384-10E-mail: [email protected]

ibg International:

ibg NDT Systems Corp.20793 Farmington RoadFarmington Hills, MI 48336Tel: +1-248-478 9490Fax: +1-248-478 9491E-mail: [email protected]

ibg SWISS AGGalgenried 6CH-6370 StansTel: +41-41-612 2650Fax: +41-41-612 2651E-mail: [email protected]

ibg UK Ltd.33 Park View RoadSutton ColdfieldGB-West Midlands B74 4PRTel/Fax: +44-121-352 1188E-mail: [email protected]

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Pretzfelder Straße 27D-91320 Ebermannstadt • Germany 0-3

Contents

Exclusion of responsibility................................................................................ 0-1

1. Introduction .................................................................................................... 1-1

1.1. What is an eddyvisor®?..................................................................................... 1-1

1.2. The principle of eddy current structure testing .................................................. 1-2

1.3. Possibilities of eddy current structure test ......................................................... 1-3

2. General information ....................................................................................... 2-1

2.1. Selection of structure test coils ......................................................................... 2-1

2.2. Creation of optimum test conditions .................................................................. 2-3

2.3. Wiring ............................................................................................................... 2-5

2.3.1. Desktop instrument ................................................................................. 2-7

2.3.2. Switch panel version ............................................................................... 2-8

2.4. Elements of the front panel ............................................................................... 2-9

2.4.1. Keys...................................................................................................... 2-10

2.4.2. Help function ......................................................................................... 2-11

2.4.3. Printer function...................................................................................... 2-11

2.4.4. Status bar.............................................................................................. 2-11

2.5. Course of measurement ................................................................................. 2-12

3. Short operating instructions ......................................................................... 3-1

3.1. Structure test .................................................................................................... 3-1

3.2. Crack detection................................................................................................. 3-5

4. Operating modes and functions ................................................................... 4-1

4.1. Station and location bar .................................................................................... 4-1

4.2. Part type selection ............................................................................................ 4-1

4.3. Setup ................................................................................................................ 4-2

4.3.1. Project & Language................................................................................. 4-24.3.1.1. Language.................................................................................... 4-2

4.3.2. Test Assembly......................................................................................... 4-34.3.2.1. Station- and location bar ............................................................. 4-34.3.2.2. Station window............................................................................ 4-3

4.3.3. Inputs and Outputs.................................................................................. 4-64.3.3.1. Selection of VCONI ..................................................................... 4-74.3.3.2. Monitor inputs, force outputs manually........................................ 4-74.3.3.3. Allow Signal Assignment ............................................................. 4-8

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Pretzfelder Straße 270-4 D-91320 Ebermannstadt • Germany

4.3.4. System Properties................................................................................. 4-104.3.4.1. Printer setting............................................................................ 4-104.3.4.2. Network setting of eddyvisor

®.................................................... 4-11

4.3.4.3. Date / Time ............................................................................... 4-124.3.4.4. Form ......................................................................................... 4-124.3.4.5. Network-Log.............................................................................. 4-124.3.4.6. Mouse pointer on/off ................................................................. 4-124.3.4.7. System monitor ......................................................................... 4-12

4.3.5. Part Type Administration ....................................................................... 4-12

4.3.6. Frequencies & Locations (general)........................................................ 4-134.3.6.1. Activate / deactivate location ..................................................... 4-144.3.6.2. Standard settings ...................................................................... 4-144.3.6.3. Discard changes ....................................................................... 4-144.3.6.4. Save settings............................................................................. 4-144.3.6.5. Save all settings ........................................................................ 4-14

4.3.7. Frequencies and locations (structure test)............................................. 4-144.3.7.1. Tolerance zone shape (ellipse / rectangle) ................................ 4-144.3.7.2. Tolerance zone factor ............................................................... 4-154.3.7.3. Frequency ................................................................................. 4-154.3.7.4. Test time and settling delay....................................................... 4-164.3.7.5. AUTOSTART Configuration ...................................................... 4-16

4.3.8. Frequencies and locations (crack detection) ......................................... 4-184.3.8.1. Band pass and tolerance zone .................................................. 4-184.3.8.2. Tolerance zone factor ............................................................... 4-194.3.8.3. Sender frequency...................................................................... 4-194.3.8.4. Tolerance zone factors commonly operated.............................. 4-194.3.8.5. Threshold .................................................................................. 4-194.3.8.6. Settling delay............................................................................. 4-194.3.8.7. End of test after … .................................................................... 4-194.3.8.8. Lift-off compensation monitoring ............................................... 4-204.3.8.9. Monitoring of probe (noise threshold) ........................................ 4-204.3.8.10. Speed monitoring .................................................................... 4-204.3.8.11. Frequency range proposals..................................................... 4-214.3.8.12. Setup Lift-off compensation..................................................... 4-21

4.4. Reference Data............................................................................................... 4-21

4.4.1. Data recording active ............................................................................ 4-22

4.4.2. Data recording stopped ......................................................................... 4-224.4.2.1. Navigation in parts .................................................................... 4-224.4.2.2. Mark reference parts ................................................................. 4-234.4.2.3. Tolerance Zone Editor (structure test)....................................... 4-23

4.5. PMFT - Preventive Multi-Frequency / Multi-Filter Test..................................... 4-24

4.5.1. Testing active........................................................................................ 4-24

4.5.2. Stop testing ........................................................................................... 4-244.5.2.1. Navigation in parts .................................................................... 4-25




4.5.2.2. Parts Counter............................................................................ 4-254.5.2.3. Screen off ................................................................................. 4-254.5.2.4. Add test part to Reference Data................................................ 4-264.5.2.5. Tolerance Zone Editor (structure test)....................................... 4-26

4.6. Display options................................................................................................ 4-26

4.6.1. Structure test......................................................................................... 4-264.6.1.1. Locus curve display................................................................... 4-264.6.1.2. Tolerance zone display - single ................................................. 4-264.6.1.3. Tolerance zone display - all....................................................... 4-274.6.1.4. Bargraph display ....................................................................... 4-27

4.6.2. Crack detection ..................................................................................... 4-284.6.2.1. Outline bars............................................................................... 4-284.6.2.2. Tolerance zone display - single (xyt-display) ............................. 4-294.6.2.3. Tolerance zone display - all....................................................... 4-304.6.2.4. C-scan display........................................................................... 4-314.6.2.5. Bargraph display ....................................................................... 4-31

4.6.3. Parts counter and history ...................................................................... 4-31

4.7. Key switch - authorisation level ....................................................................... 4-32

5. Data recording via network with eddyLogger.............................................. 5-1

6. Connection with automatic sort systems .................................................... 6-1

6.1. Automatic test, program course ........................................................................ 6-1

6.2. Time diagram.................................................................................................... 6-2

6.3. Electronic diagram of interfaces........................................................................ 6-4

6.3.1. Proposal for Signal Assignment .............................................................. 6-6

6.4. Example Opto-Interface .................................................................................... 6-7

6.4.1. Current supply for in and outputs ............................................................ 6-7

6.4.2. Interface for universal sorting device....................................................... 6-8

6.4.3. Test on consecutive locations controlled by PLC .................................... 6-9

6.4.4. Part type switching controlled by PLC ................................................... 6-10

6.5. Coil connection VCONS (structure test) .......................................................... 6-11

7. Part type switching via PLC (structure test) ................................................ 7-1

7.1. Part type switching controlled by PLC............................................................... 7-1

7.2. Part type request controlled by PLC.................................................................. 7-2




8. Technical data.................................................................................................8-1

9. Glossary ..........................................................................................................9-1

10. Appendix .....................................................................................................10-1




1. Introduction

We congratulate you on the decision to employ the eddyvisor® in your factory. Withthis instrument you have acquired the most advanced eddy current testing deviceworking according to the PREVENTIVE MULTI-FREQUENCY TEST as well as thePREVENTIVE MULTI-FILTER TEST (PMFT). Successful implementation of a testpresupposes, in addition to a full command of the instrument settings, also a solidknowledge of the product to be tested, its material properties, of the errors likely tooccur and their underlying causes.

The tester must be conversant with the limitations and restrictions in errordetectability as well as with the efficiency of the equipment used and with its properfunction. It is the proper functioning that needs to be checked prior to every test andperiodically during operation in order to warrant reliable test results. If theserequirements are not satisfied, the result will be of questionable value.

Should you have any further questions or need our advice for an optimum solutionof your testing problem, please do not hesitate to contact us. Our after-sales serviceis ready to help you at any time.

Chapter "3. Short operating instructions" from page 3-1 is mainly intended to savethe users who are not constantly working with the eddyvisor® the troublesomestudy of a detailed user manual.

As a new user of the eddyvisor® you should simply try to perform a test with thisunit under the guidance of the "3. Short operating instructions" before going throughthe detailed user manual and the fine adjustment of all parameters. You will besurprised how quick you will learn to handle the eddyvisor

®.

Please read these concise operating instructions carefully in order to avoidoperating errors. We have tried hard to keep the instructions as short as possible inan effort not to burden you with unnecessary information.

1.1. What is an eddyvisor®?

The eddyvisorS is an eddy current test instrument for Structure test using PMFT

Preventive Multi-Frequency Test. This enables testing e.g. for material mix,hardness, case depth, material composition as well as material texture ofconductive materials.

The eddyvisorC is an eddy current test instrument for Crack detection using

PMFT Preventive Multi-Filter Test. This enables testing e.g. for surface-opencracks or disturbances of surface texture of conductive materials.




The eddyvisorSC combines both test methods (Structure & Crack test) in one

instrument.

1.2. The principle of eddy current structure testing

When alternating current is sent through a transmitter coil, a magnetic field buildsup at the coil. If a conductive test specimen approaches the current-carrying coil, aneddy current is induced in the test specimen. This phenomenon is schematicallyillustrated in fig. 1.1.

um us

siu

u

2

1

wi

Figure 1.1

The magnitude of the eddy current depends on the chemical composition (alloy) andon the structural condition (e.g. hardened). By changing the eddy current frequency,an electromagnetic "thumbprint" of the structural state is obtained in the coil system.This can be picked up by the instrument through the integrated receiver coil andevaluated.

An alteration in the structural state, in the alloy and the like attributable to a mix-upof material, a batch mix or faulty thermal treatment causes also the eddy currentsignal to change. The eddyvisorS testing device recognizes such changes and

indicates deviations.

The eddyvisorS operates according to the method of PREVENTIVE MULTI-

FREQUENCY TESTING (PMFT) developed by ibg. The merit of PREVENTIVEMULTI-FREQUENCY TESTING is seen in the high probability of detecting evenunknown flaws on account of the broad frequency band selected.

In contrast to other procedures, ibg uses low field strength values. This means thatonly low currents flow through the coils and that low permeabilities develop inferromagnetic materials (initial permeability).




This method affords the following advantages:

It operates at the higher penetration depth of the eddy current so that theinfluence exerted by the marginal layers is reduced.

The reproducibility of the measurements is guaranteed because no magneticalterations develop in the structure of the specimen.

Improved testing stability because no heat builds up in the specimen, theinstrument and in the coil.

The salient properties of PREVENTIVE MULTI-FREQUENCY TESTING (PMFT) arethe following:

Maximum testing reliability - even unknown flaws are identified without fail.

Only good parts must be presented to the instrument.

The generation of tolerance zones is extremely simple and made in a very shorttime.

1.3. Possibilities of eddy current structure test

Eddy current inspection can be applied to any type of material being conductiveeither electrically or magnetically. This holds good for all metallic materials.

The eddyvisorS takes care of all the fields of application summarily mentioned in

table 1.1.

Type of parts Parameters to be tested for

Forged piecesBearing componentsVA-tubesScrewsBrake discsPower transmission elementsComponents of belt locksLinear guidesBalls

heat treatment and material mix-uphardness and material mix-upmaterial mix-upheat treatmentchill depthpurity and core strengthhardness and texturepurity and grinding burnmaterial mix-up

Table 1.1

Please note that the eddy current inspection procedure is not an absolutemeasuring method but rather a comparative approach. The hardness of parts canbe measured with the eddyvisorS inspection device to within 2-3 HRC without

any problem. However, as is the case with all eddy current tests, the inspection is




based on YES/NO answers. The eddy current testing instrument does recognizedeviations from existing tolerance zones, but cannot reveal the causes responsiblefor them. In order to obtain precise information on why the specimens wereclassified as not being in order, yet other testing procedures such as hardness testand metallographic studies must be employed to confirm the findings of the eddycurrent device.




2. General information

The eddyvisor® eddy current inspection device is multiprocessor-controlled. Theentire control software is configured hierarchically, so the selectable submenusautomatically result from each main menu. The eddyvisor® is operated via a so-called soft key control system which enables the user to handle the device with arestricted number of keys.

These operating instructions have been arranged so that each step of operation isexplained in chronological order. All you need to do is to execute the instructionsstep by step as indicated. While proceeding in this manner, you are guided throughthe complete software.

Hint

The [?]-is auxiliaryand serves to indicate a context-related help at any time.

This means that the help needed is offered at any point of thesoftware.

The key combinations to be actuated by the user are written inbold capital letters throughout the User Manual.

Should you nevertheless experience any problem with operation,please contact us under the following telephone number:

ibg Prüfcomputer GmbH, Tel. +49-9194-7384-0

2.1. Selection of structure test coils

Selection of the proper test coils and probes is of decisive importance for the testresult. In addition to a set of standard coils and probes, special coils adapted to thejob are available. The selection of suitable coils determine the type of job and theshape of the specimen. Here the following criteria should be considered:

What is the job like?e.g. measurement of the case depth of shafts

Which coil should be used?The suitable coil or probe can be taken from table 2.1.




Field of application Frequency range

Pro

be

En

cir

cli

ng

co

il

En

cir

cli

ng

co

ilsh

ield

ed

Recta

ng

ula

rco

il

Fla

tco

il

Material mix:

ferritic materialaustenitic materialnon-ferrous metalshard metals

25 Hz - 100 kHz100 Hz - 100 kHz100 Hz - 100 kHz

50 Hz - 100 kHz

+++++++

++++

++

+

+

++++

++

+++++++

Heat treatment:

temperingsurface hardnesscase depth of shaftscase depth (carburized)carburizationdecarburization

25 Hz - 25 kHz100 Hz - 25 kHz

5 Hz - 400 Hz5 Hz - 4 kHz5 Hz - 25 kHz

10 kHz - 100 kHz

+++

––

+++

++++++

+++

++++

+

++

++++++

+++

+++

––

+++

Cast iron:

nodular cast ironledeburite (spherocast)

5 Hz - 5 kHz25 Hz - 25 kHz

+++

+++

++

+++

+++

Surface:

grinding abuse 5 kHz - 100 kHz ++ ++

++ very good + good possible – not possible

Table 2.1

Our standard coils are classified by frequency ranges. Whereas the frequencyrange of the encircling coils is directly indicated on the name plate, the probes arecoded as follows:

1 ring 25 Hz to 10 kHz2 rings 250 Hz to 50 kHz3 rings 5 kHz to 250 kHz

As far as encircling coils are concerned, a filling degree of less than 60 % shouldnot be selected as otherwise the measuring signals become too small and thedifferences, say, in the case depth are no longer recognized distinctly. When usingencircling coils, a second coil is required for compensation. This coil must feature a




firmly (!!!) mounted compensation part. Removing or shifting the compensation partleads to wrong test results. The compensation part has no comparing functiondesigned to distinguish the OK-parts from the NotGood-parts.

The basic design of the standard encircling coils is displayed in Fig. 2.1. Each coilcontains a transmitter and receiver winding. The receiver winding should always bearranged as close as possible to the area to be measured. It is very easy to find outon what side the receiver or transmitter windings are located. Just take an encirclingcoil and read the name plate. If you can read this plate and when the coil plug is onthe left of you, the receiver winding is below and the transmitter winding is above inthe coil.

25Hz-25kHz

P/NS/NDAT

ibg

Section A-A

Coil plug

Receiver winding

Transmitter winding Frequency range

A AA

Figure 2.1

For coil protection wearing bushes of abrasion-resistant plastic material e.g."Murtfeldt S green" should be used.

2.2. Creation of optimum test conditions

Be sure to pay attention to the following points when carrying out a testing job.Carefully read the following hints. Disregarding them is likely to lead to faultymeasurements. The eddy current procedure is no absolute method.

The following parameters may cause the results to scatter:

Inhomogeneities in material

Dimensional tolerances in the specimen

Dimensional tolerances in coil or probe positioning




Variations in temperature (structure test)

For optimum results please pay attention to the following points:

Make sure that the parts used for Reference Data really comply with the desiredspecifications.

Show at least 5 OK parts to the instrument as Reference Dataat least 10 OK parts when structure testing.

Select reasonable tolerance sizes.To avoid the risk of undesirable pseudo rejects.

Do random checks during testing with OK and NG parts.

Lock the instrument with the keyswitch to avoid unwanted access.

Read the operating manual before initial operation.

Provide constant and reproducible test conditions.

Avoid interferences near the coil resp. probe such as current impulses, fluxsetups active during the measurement, electric welding and other magnetic orelectric interference fields.

In addition for structure test:

Different batches should be tested separately.The best results are obtained if for each material batch an own part type (withown reference data) is used.

Please see to it that the test parts have constant test temperature.

Please see to it that no metallic parts, which are not marked for testing, arelocated near the test coils.

Carry out the test on a wooden table, if possible. Even steel girders underneath awooden board are likely to affect the test results.

The following factors may adversely affect the measurement directly:

Positioning of the specimen in the coil resp. in relation to the probe (distance).

Dimensional tolerances of the specimens.

Structure test: variation in batches or differences in temperature betweencalibration part and test part.




Use of coils resp. probes with a wrong frequency range.

Lift-off effect due to dust and dirt.

Edge effect caused by measuring near edge of part

2.3. Wiring

Prior to putting the eddyvisor® into operation, all cables must be connected and allconnections to be checked.

WARNING

Please take care that all cables are plugged and screwed tightbefore the power switch is turned on.

The instrument must be grounded properly (PE connector of themains plug or grounding screw on the instrument housing, seedrawing of the back side of the instrument below). Otherwise,voltage may constitute on the housing. If the instrument is not

grounded properly, the safety standard protective ground are notobeyed. Furthermore, quality of testing is impaired so that

optimum test results cannot be achieved.

Also ensure that all plugs are firmly connected and screwed tight.

If plugs are inserted after connection of the eddyvisor® thevarious components are likely to be damaged!

The eddyvisor® consists of the operating unit eddyvisor®HMI and the measuringunit for structure resp. crack test eddyvisor®MSC (refer to "9. Glossary"). Both unitscommunicate via USB interface.

Both units are connected to one unit as eddyvisor® desktop instrument. Powersupply is effected via the measuring unit. USB coupling of the single parts is doneinternally without using the USB jack of the measuring unit.

Operating and measuring unit are supplied separately when using the eddyvisor®

in a test system. Both units have to be supplied with line voltage. USB coupling ofthe single parts is done via one of the protected lower USB jacks of the operatingunit and the USB jack of the measuring unit.




OS-CompactFlash(CF)

Ethernet-jack

mains plugfine-wire fuse T 2.0A

USB-jacks(refer to text)

Figure 2.2

Figure 2.2 shows the bottom side of the operating unit eddyvisor®HMI. An ibg CF-card has to be used in the CF-slot. The lower one of the two USB jacks is used forconnection of measuring unit of the eddyvisor

®. The Ethernet jack enables

connection to a network printer, a company network resp. a PC/laptop.




2.3.1. Desktop instrument

type plate mains plus and fine-wire fuse T 2.0A

coil connection boardVCONS2 (structure test)

I/O-boardVCONI

probe connection boardVCONC2 (crack test)

slot-no.

Figure 2.3

Figure 2.3 shows the connector side of the measuring unit. It is an eddyvisor®DSCfor structure test with max. 2 coils and crack test with max. 2 probes. Slots 1 - 4include exchangeable boards.

Slot 1 includes a coil connection board VCONS2 (for structure test) for use withmax. two coils - „A1“ and „A2“. Up to 8 coil connections per slot are possible(VCONS8).

Slot 2 includes a probe connection board VCONC2 (for crack detection) for use withmax. two probes - „A1“ and „A2“. Up to 4 probe connections per slot are possible(VCONC4). Each probe connection board VCONCx requires internally a channelboard VKAN.

Slot 3 includes an I/O-board VCONI for connection of 16 in- and 16 outputs 24 Vdcper D-sub plug. Power supply of the I/O jacks is effected either via D-sub plugs or




via bridges at the 24V power supply plug „C“. I/O-boards VCONI may be used onlyeither in slot 3 or in slot 6 or in slot 7.

Slot 4 includes a mains supply board. Plug „A“ shows the mains supply of themeasuring unit. Power supply of the operating unit of a desktop instrument iseffected internally. Plug „B“ shows the USB jack of the measuring unit forconnection with a separate operating unit. The USB jack of the measuring unit ofthe desktop eddyvisor

®is not wired.

At desktop eddyvisor®, only slots 1 - 4 of the measuring unit are accessible.

2.3.2. Switch panel version

At test systems, eddyvisor® with separate operating and measuring unit, all slots (1- 7) of the measuring unit are accessible. Slots 1 - 4 are at the outside of the switchcabinet, slots 5 - 7 are inside.

Slots 1 - 4 includes coil connection boards VCONSx and crack detection probeboards VCONCx and point to the test mechanic. Slot 5 is equipped with the mainssupply board and slots 6 - 7 with I/O-boards and point to the PLC.

Important note!

The eddyvisor®

must be properly earthed: PE-connector of themains plug or earthing screw on the housing of the measuring unitin test systems. Otherwise, voltage may constitute on the housing.

If the instrument is not earthed properly, the safety standardprotective ground are not obeyed. Furthermore, quality of testing

is impaired so that optimum test results cannot be achieved.




2.4. Elements of the front panel

The eddyvisor® is operated on the front panel of the operating unit. Figure 2.4shows the front panel.

key switch

(b)

(a) (c)

ON-function lamp 2x USB jack touch panel

Figure 2.4

Touch panelThe touch panel displays information and serves as key keyboard. The menusare explained in the following chapter.

USB-jacksThere are two USB jacks behind a sliding cover in order to save or recallsettings.

ON function lampA blue LED is on when the instrument is on.

Key switchThe key switch has 3 positions. The key may be taken out at all 3 positions.

(a) The instrument is switched off (separated from the power line).




(b) The instrument is switched on. All functions are accessible.

(c) The instrument is switched on. Restricted access to functions of theinstrument. Use: No unauthorised access at running test possible.

When turning the key to position (c) a window appears. Here the rangeof access restrictions may be chosen.

2.4.1. Keys

The operation of the eddyvisor® is carried out via the displayed keys on the touchscreen. The meaning of the keys is explained by the screen text. Further help ispossible by pressing the [?]-key and then the key to be explained.

At the left side of the touch screen, in many operating modes, stations and locationsare displayed resp. selected.

At the upper edge of the touch screen, the main navigation bar is displayed. Thecurrent operating condition can be seen by the pressed key.

At the right side of the touch screen, different function keys are displayeddepending on operating mode.

Figure 2.5 shows (as example) the help for the reference data menu.




printer help

date, timetest-infodemo-modeserial numberev software version

help text

status bar

Activate Ref.-Data Recording /Data Recording active

Here, a station is set to condition reference data recor-ding.The first activated position of a station is nowsensitive for incoming start signals, as soon as it isstarted all other activated positions are sensitive forstart signals as well.When pressing the key "Data Recording active" isdisplayed within the key.When "station states are operated together" is set inSETUP - test assembly all stations are activated.

Stop Ref.-Data Recording /Data Recording stoppedAfter the reference data for the parts are recorded

the reference data recording for the station may be

Figure 2.5

2.4.2. Help function

The eddyvisor® provides a context-relating help. By pressing the [?]-key and thenthe key to be explained help is called. Figure 2.5 shows the help for reference datamenu.

2.4.3. Printer function

The eddyvisor® enables documentation by using screen prints. By pressing theprinter-key the menu for printing of the current screen is called. Printing to a printer(set in "Setup" / "System settings") is possible, or a screenshot can be stored to amemory stick, storable in different formats.

2.4.4. Status bar

The status bar is at the lower edge of the screen. The following information aredisplayed:




EV XX.XXXSoftware version of eddyvisor®

S/N: XXXXXSerial number of the eddyvisor®

in DEMO-modeThe word "DEMO" is red-blinking. All functions can be used in demo mode. Anymodifications of settings, however, are not saved. Any changes get lost whenswitching off the instrument.

"Neg: xx Id: xx Err: xx"Debug information for ibg.

"Authorisation: ..." in horizontal, right-hand keyswitch position:The current authorisation level e.g. "authorisation: basic position" is displayed.

Activity display (structure test at reference data recording or testing):Display of the current measuring e.g. "Calibration" for automatic calibration;"S1/P2 Settling Delay", "S1/P2 Testing" for station 1 / location 2 in settlingdelay resp. measuring.

Date and time in format year-month-day hour:minute:second.

2.5. Course of measurement

The eddyvisorS operates on the ibg-developed principle of PREVENTIVE

MULTI-FREQUENCY TESTING (PMFT). After the measurement has beentriggered, the test frequencies are applied successively to the coil system, startingat the lowest test frequency. At each test frequency the response of the specimento the coil system is recorded and the electric voltage vector is broken down into itsX and Y components and stored.

Upon completion of the test, the values stored are, depending on the operatingmode, either compared with the tolerance zones (mode SORTING) or assigned tothe material data (mode RECORDING O.K. PARTS).

STARTx (start pulse)

settling delay

BUSY-S(structure test runs)

OKx (sort output Gut)

ENDx (end of measuring)




Measurement starts with the "START-Signal":

Measurements are started with the START-signal and need a certain time (BUSY-S-signal). A measurement can only be triggered in mode REFERENCE DATA orPREVENTIVE MULTI-FREQUENCY TEST.

Settling delay:

After starting a test, but before the test proper begins, the operator may select anadjustable settling delay. This delay allows the specimen to "settle inside the testcoil", so the test will only be started as soon as the part has taken up its finalposition in the coil.

The "BUSY-S-signal":

If the test unit functions in one of the two operating modes REFERENCE DATA orPREVENTIVE MULTI-FREQUENCY TEST the BUSY-S-signal (BUSY, structuretest) will appear immediately following the START-signal. The settling delay startsrunning and upon expiration the test proper commences at the first frequency.

If the start of the following location is set to AFTER „▼“ the settling delay of this location is immediately started, the BUSY-S-signal remains active.

If it concerns, however, the last channel within a test block the BUSY-S-signaldisappears. Disappearing of the BUSY-S-signal means that the eddyvisorS is

ready to start a new measurement.

The sorting decision with the "OK-i-signal":

After testing a location at all frequencies the sorting decision is made andtransmitted to the sort outputs (OK-i-signal, NOK-i-signal). In mode REFERENCEDATA no sort signal appears.

The sum sorting decision with the "OK-S-" and "NOK-S-signal":

After testing all locations of one station the sorting decision for the station is madeand transmitted to the sort output (OK-S-signal and NOK-S-signal). For this, theformation of the sum signal OK-S must be set. In mode REFERENCE DATA no sortsignal appears.

The END-i-signal:

After testing a location at all test frequencies the allocated END-i-signal appears.




The sum signal END-S:

After testing all locations of one station the sum signal for the station is made andtransmitted to e.g. the output END-S. For this, the formation of the sum signal END-S must be set.




3. Short operating instructions

3.1. Structure test

These concise operating instructions are intended to show you, that theeddyvisorS enables you to obtain test results in a short time, whenever projects

are available. A standard project 'screw test' (DEMO mode) is used here. It isadjustable in the menu SETUP, PROJECT & LANGUAGE.

Below are the sequence of steps to be executed:

(a) The probe resp. the coils are directly connected to the measuring unit ofthe eddyvisorS, coil board VCONS in slot 1 and jack A. Using

encircling coils: one part is put into the compensation coil(s). Using self-compensated coils or probes: no compensation part needed.

(b) If operating and measuring unit are separate they have to be connectedvia a USB-cable.

(c) Connect eddyvisorS to mains supply. If operating and measuring unit

are separate both units must be supplied with mains voltage.

(d) Prepare at least 10 (better some more) OK parts (as reference).

(e) The characteristic eddy current data are recorded by "showing" the knownOK-parts. The eddyvisorS automatically forms tolerance zones.

(f) The specimens are tested by comparing their eddy current characteristicswith the tolerance zones formed by the material data and sorting based onGood (OK) and NotGood (NOK) criteria.

Now proceed step by step as indicated in the short operating instructions.

The standard configuration of the eddyvisorS includes already a test

configuration. This standard configuration is accessible via menu SETUP,PROJECT & LANGUAGE, STANDARD PROJECT ... (DEMO MODE). Any changesto this demo project will get lost when switching off the eddyvisorS or leaving the

demo mode.

Switch on the instrument with the key switch, key in vertical (middle) position.

Select the standard project 'screw test' (DEMO mode) in the menu SETUP,PROJECT & LANGUAGE.

Then select the main menu REFERENCE DATA.

The eddyvisorS now displays the MAIN MENU and has loaded a project

available in the internal memory. In the upper left-hand corner, the currently active




part type can be seen, here type 001, generated on 2005-06-01 (year-month-day),name "type", "no. 01". REFERENCE DATA is selected in the main menu.

main menupart typeselection active menu, condition

sub menu

station,state

Figure 3.1

press REFERENCE DATA (if necessary)The mode REFERENCE DATA becomes active. In this mode, OK parts are readin and tolerance zones are formed. A tolerance zone with REFERENCE DATARECORDING STOPPED appears and on the right-hand side the relating menu.

press ACTIVATE DATA RECORDINGThe mode changes to REFERENCE DATA RECORDING RUNS. The stationkeys get a small yellow arrow symbol which means the release for referenceparts recording.

Put one OK part resp. the coil to test position and press the START-keyon the eddyvisorS. Measuring values via the set frequency are

recorded for the part and displayed in the tolerance zone.

Change the OK parts and press the START-key on the eddyvisorS.

Further measuring values are recorded. The value of the latest referencepart is specially displayed. At the same time tolerance zones are formedrelating to the measuring values. These tolerance zones are used for thesucceeding test for comparison.




PREVENTIVE MULTI-FREQUENCY TEST

latest recorded parts

tolerance fieldsstation,release

displayoptions

history

location

Figure 3.2

Press PREVENTIVE MULTI-FREQUENCY TEST in the main menu. Themenu PREVENTIVE MULTI-FREQUENCY TEST becomes active.Several small tolerance zones appear one below the other and the modePMFTesting active is displayed. The station number has a small greenarrow symbol which means the release for parts testing.

Put the part to be tested resp. the coil into test position and press theSTART-key on the eddyvisorS. If the part is good (OK) a green OK

symbol goes on. If the part is bad (NOK) a red NOK symbol goes on. Atthe same time bargraphs are displayed for each measuring frequencymirroring the relative position of the measuring values regarding thetolerance zone. The position of the measuring value is indicated in thetolerance zones.

Change the part to be tested and again press the START-key on theeddyvisorS. The maximum deviations of the latest recorded parts

appear as bargraphs in the lower part of the screen besides the smallhistory of the test results.




The display options are bargraph diagram, local material curve andseveral tolerance zones. When displaying the results of a singlefrequency the bargraph changes to a display of values of this frequency.NOK parts are marked in red.

As per this course all parts to be tested are verified at all locations.

PREVENTIVE MULTI-FREQUENCY TEST, press STOP TESTING.The mode changes to STOP TESTING. The station numbers get a smallblack double-bargraph symbol which means lock regarding parts testing.The submenu changes and two yellow arrow keys appear besides theparts statistic.

Pressing "Reset parts counter" opens a window with a safety request ifparts counter and sorting data are really to be deleted. In doubtful casesay no.

Between the latest recorded parts may be changed by pressing the yellowarrow keys. For a quicker change the selection may be limited to OKparts and NOK parts. The selection is done via a switch besides thestatistic.

Pressing "Add tested part to ref data" enables adding of a part to thereference data. A safety request avoids adding of parts by mistake. Partswhich have been added for trial purposes may be marked as invalid anddeleted in REFERENCE DATA menu.

Press the PRINTER symbol on the eddyvisorS in order to print a test

protocol. An inquiry window appears. You can select between printing thescreen as picture file in a certain format or printing the protocol on aprinter. The just running sort test is not influenced by the printing process.

3.2. Crack detection

These concise operating instructions are intended to show you, that theeddyvisorC enables you to obtain test results in a short time. Starting point is the

factory setting. For this, "Standard settings" in menu "Setup" / "Project & Language"are called.

Below are the sequence of steps to be executed:

(a) The crack detection probe is connected with the measuring unit of theeddyvisorC, to the probe connection board VCONC in slot 1, jack A1.

(b) If operating and measuring unit are separate they have to be connectedvia a USB-cable.

(c) Connect eddyvisorC to mains supply. If operating and measuring unit

are separate both units must be supplied with mains voltage.

(d) Prepare at least 5 (better some more) OK parts (as reference).




(e) Recording of characteristic noise of the surface (as eddy current data) by"showing" of these OK parts. The eddyvisorC automatically generates

tolerance zones.

(f) The specimens are tested by comparing their eddy current characteristicswith the tolerance zones and sorting based on Good (OK) and NotGood(NOK) criteria.

Now proceed step by step as indicated in the short operating instructions.

The standard configuration of the eddyvisorC includes already a test

configuration. This standard configuration is accessible via menu SETUP,PROJECT & LANGUAGE, STANDARD SETTING.

Switch on the instrument with the key switch, key in vertical (middle) position.

Select the "standard setting" in the menu SETUP, PROJECT & LANGUAGE.

Then select the main menu REFERENCE DATA.

The eddyvisorC now displays the MAIN MENU and has loaded the standard

setting. In the upper left-hand corner, the currently active part type can be seen,here type 001, generated on 2007-05-09 (year-month-day), name "type", "no. 01".REFERENCE DATA is selected in the main menu.

main menupart type functionkeys

station,state

Figure 3.3




press REFERENCE DATA (if necessary)The mode REFERENCE DATA becomes active. In this mode, OK parts are readin and tolerance zones are formed. The minimum tolerance zone of one of 30band passes is shown. The station condition "stopped" is visible on the left-handside in the station key and on the right-hand side at condition of function key.

press ACTIVATE DATA RECORDINGThe mode changes to REFERENCE DATA RECORDING RUNS. The stationkeys get a small yellow arrow symbol which means the release for referenceparts recording.

Put one OK part resp. the probe to test position and start rotation of partresp. probe. Press the START-key on the eddyvisorC. Now the noise

signals of the surface are recorded and displayed live. If testing includesa surface scan do the advance movement (the scan) now. It is normalthat the signals of the first reference part are displayed very large asdisplay is done with the largest amplification.

After the scan press the STOP-key on the eddyvisorC. A "polar field"

is automatically formed around the signals taken between START andSTOP and displayed in orange. This happens in the xy-display for each ofthe 30 band passes. The green tolerance zones are calculated of thepolar fields of all reference data plus the tolerance zone factors and aredisplayed.

Now change OK part and do the same procedure; start rotation, pressSTART on eddyvisorC, do scan, press STOP on eddyvisorC and

stop rotation.So the measuring values for further reference parts are taken. Themeasuring value of the latest reference part are displayed. At the sametime, tolerance zones to the measuring values are formed. Thesetolerance zones are used for the following test for comparison.




PREVENTIVE MULTI-FILTER TEST

latest recorded parts (history)

tolerance fieldsstation,release

displayoptions

parts counter

location

Figure 3.4

press Preventive Multi-Filter Test in main menuThe menu Preventive Multi-Filter Test becomes active. Several small tolerancezones appear one under the other and the station condition changes to "testactive". The station numbers get a small green arrow symbol indicating releasefor parts testing.

Put the test part resp. the probe in test position, start rotation, press the START-key on the eddyvisorC, scan, press the STOP-key on the eddyvisorC.

If the part is good (OK) a green symbol goes on. If the part is bad (NG) a redsymbol goes on. At the same time, bars for each band pass are faded in whichshow the size of the signal in relation to the tolerance zone.

Change the part and do the same procedure (rotation, start, scan, stop) for eachpart. The maximum deviation of the latest recorded part appears as barsequence in the lower part of the screen as small history to the test results.

Pressing the display options shifts between bargraph display, xyt-display (withpolar- and tolerance zone) and C-scan-display. Displaying the results of a singleband pass, the history does only show this one band pass, too.The red/green indication of result left ahead always refers to the sorting result ofthe complete station, i.e. the result of all bad passes.




As per this procedure all parts to be tested are checked at all locations.

press Stop testingThe station condition changes to testing stopped. The station numbers get asmall black double-bargraph symbol indicating lock regarding parts testing. Thefunction keys change and two yellow arrow keys appear beside the partsstatistic.

Pressing "reset parts counter" opens a window with a safety request if the partscounter and the sorting data are really to be deleted. In doubtful case say no.

The yellow arrow keys enable switching between the latest recorded parts. Forquicker change, the selection may be limited to OK or NG parts only. Selection isdone via a key beside the statistic.

Pressing "Add test part to RefData" allows adding of a part to the reference data.A safety request avoids erroneous adding of parts. In reference data menu,added parts can be marked as invalid and removed for test purpose.

Press printer symbol on eddyvisorC

To print a test protocol when a printer is connected. An inquiry window appears.You may decide whether the current screen is printed as picture file in a certainformat or whether a protocol is printed. The running sorting is not influenced byprinting.




4. Operating modes and functions

The main menu of the eddyvisor® includes:

SetupProject settings of the eddyvisor®

Reference dataRecording of reference parts to generate tolerance zones

Preventive Multi-Frequency / Multi-Filter TestTesting of parts and sorting to OK and NG

4.1. Station and location bar

A station bar on the left-hand side of the screen allows to select single or allstations. The single station keys get a coloured icon to mark the current condition ofthe station:

two black rectangles on the lower left-hand side:station stopped.

yellow triangle on the upper left-hand side:station in reference data recording

green triangle on the upper right-hand side:station in Preventive Multi-Frequency Test

A location bar is positioned beside the station bar. Depending on the selectedstation the corresponding locations are displayed. Single or all locations areselectable via the locations keys.

If a station / location and bargraph display are selected, a list of test frequencieswith their letters A - H appears beside the location bar.

4.2. Part type selection

The key on the upper left-hand side of the touch screen shows the current part type.

Press this key and a menu "Overview of saved Part Types" appears. A list ofavailable part types is shown. The list may be sorted according to number of part,caption 1, caption 2 or date by pressing the key in the headline. Repeatedlypressing the key inverts sorting sequence.




Part types are selectable via the arrow keys on the left-hand side of the list. Aselected part type is loaded into the current resp. all stations by pressing „Loadonly in this Station“ and "Load in all stations" and the menu is left. The key"Cancel" leaves the menu without any changing.

For further information see chapter SETUP - Part Type.

4.3. Setup

All settings of the eddyvisor®

are done in menu SETUP. It is subdivided into thefollowing points:

Project & LanguageSetting of language, storage and restorage of settings of the instrument to resp.from the USB storage medium (USB-stick) as projects.

Test assemblyTest assembly describes the stations with their locations and the relating coilsand logical signals.

In- and outputsAllocation of logical signals and physical in- and outputs.

System settingsBasic settings like printer, integration of eddyvisor® into a network anddate/time.

Part typeCreation of individually named part types for use with test assembly.

Frequencies & LocationsSetting of band passes, settling delay and test times and versatile monitoringfunctions. If used, also setting of lift-off compensation.

4.3.1. Project & Language

Menu of eddyvisor®

to select language and to load and store the current project.

4.3.1.1. Language

The language of the user interface is selected. Pressing a key causes immediateswitching of language.




4.3.2. Test Assembly

Test Assembly describes the stations with their locations and the relating coils andlogical signals.

Pressing the key "Default Settings" sets test assembly to standard settings. Thistest assembly includes a station with one location.

Modifications of the complete test assembly are taken by key "Save all stations" orthe latest conditions are restored by key "Undo". If menu is changed a safetyrequest asks if to use the modified test assembly resp. to undo or to cancel menuchange.

4.3.2.1. Station- and location bar

Stations and locations are selected, added or deleted via the station and locationbar on the left-hand side of the screen.

Pressing the key "Add Structure STATION" completes the station bar by astructure test station. Pressing the key "Add Crack STATION" completes thestation bar by a crack test station. 8 stations are the maximum.

A selected station is deleted by pressing the key "Delete STATION". The remainingstations are numbered anew.

Locations may be added or deleted to resp. from a station by pressing the key "AddLOCATION" or "Delete LOCATION". Added locations get automatically the basicsettings. Maximum 32 locations are totally possible for all stations.

4.3.2.2. Station window

The test assembly of the selected station is shown in the station window. The nameof the station is shown in the upper left-hand corner.

The key "Station states will be operated together / individually" determines if allstations switch between the modes „reference data recording running“ resp.„...stopped“, „Preventive Multi-Frequency Test running“ resp. „...stopped“ at thesame time or individually.

In the upper part of the station window each location has a bar with parameters. Ifthere are more locations than can be displayed a scroll bar is shown. Below thereare sum information on the station and the amount of locations.

Coil resp. probe




In general, a pair of coils is used for structure testing, one test coil and the relatingcompensation coil.

Crack detection uses probe w/o or with lift-off compensation.

The pair of coils / the probe is connected to the VCONS / VCONC. Connection plugis shown in format:

VCONS-slot (1 - 4), connector VCONS (A or B), pair of coil (1 or 2)

Example: coil „1A2“ means VCONS in slot 1, connector A, pair of coil 1.

The coil is set in the same way for all locations of a station in the location barindividually or via the key "coil". When selecting a coil, an overview appearsshowing all possible coil connections. Touching same key again closes theoverview. Touching a marked coil proposal in the overview takes it.

Coil monitoring is set either "ACTIVE" or "not active". If coil monitoring is activethe test coils are monitored for short-circuit or break. In case of any failure testing isstopped and a failure message appears on the screen.

Start Signal

Start of reference data recording or Preventive Multi-Frequency Test is triggered bya logical start signal. The logical start signal of a location knows different startmodes:

START 1..32Triggering of start via rising edge at one input of a VCONI-board. It isrecommended to use START-i signals of standard pin assignment only.

Conti (structure test only)Continuous triggering - the start signal is triggered automatically in shortintervals (approx. 20 msec.). Application: triggering of the first test of a stationwhich permanently tests.

AFTER, symbol “▼” (structure test only) Automatic start trigger after testing of the previous location. Application:triggering of the succeeding measuring in a coil head with several locations.

AutoStart (structure test only)Automatic triggering when a test part approaches the test coil. AutoStartfunction has to be set individually in menu "Frequencies & Locations“.

External, “Ext.” (structure test only)Use of an external START-key which is connected to the coil plug e.g. structuretest probes with integrated START-key.




Manual, short “Manu” (structure test only)Triggering of start only by START-key on the eddyvisor®. The START-key ofthe eddyvisor

®may be used always for alternative triggering of a test unless

locked by the key switch.

Method of start is set individually in the location bar or via the superset Start-key„logical Input“ for location 2 or higher. When selected an overview of the methodof start appears, pressing again closes the overview. Pressing a method of starttakes it.

Sort signal

During Preventive Multi-Frequency Test an OK-i signal (OK-1..32 resp. OK-S) andNOK-i signal (NOK-1..32 resp. NOK-S) is created after the sorting decision of oneor all locations. The sum signal "Result LOCATION 1-…" indicates that all locationsare OK.

The logical signals are assigned to a pin in menu "In and outputs". Description is asfollows:

VCONI-slot (3,6,7), connector on VCONI (A or B), pin (1..37)

Example: „3A11“ means VCONI in slot 3, connector A, pin 11.

If several outputs are assigned to one signal only one pin is given. It isrecommended to use signals of the standard pin assignment only.

The signal used is set for all locations individually in the location bar or via thesuperset key sort signal "logical Output". The sum signal is determined in the bar"result LOCATION 1-…". When selected an overview of all possible sort signalsappears. Touching again closes the overview. Pressing a sort signal in the overviewtakes it. The symbol "---" removes the assignment.

The time of sort signals is set individually for each location or via the superset keysort signal "Time" for all locations the same. Duration of sum signal is set in thebar "result LOCATION 1-…". When selecting a menu appears with the followingpossibilities:

Arrow keys “▲” and “▼” allow to set a duration between 10 ms and 1,000 msec.

SYNC_0the sort signals disappear when start trigger (the start signal) disappears orwhen the station is stopped.




SYNC_1the sort signals disappear when the next start trigger (the next start signal)arrives or when stopping the station.

SYNC_2the sort signals disappear just before the next sorting decision or when stoppingthe station. Thus a maximum duration of sort impulse length is achieved.

End Signal

After measuring of one resp. all locations, an END-i signal (END-1..32 resp. END-S)may be created. The signal used is set individually in the location bar or via thesuperset key end signal "logical Output" for all locations the same. Whenselecting an overview appears of all possible end signal. Touching again closes theoverview. Pressing an end signal in the overview takes it. The symbol "---" removesthe assignment.

The time of end signal is set individually for each location or via the superset keyend signal "Time" for all locations the same. The duration of sum signal is set inthe bar "result LOCATION 1-…". When selecting a small menu appears to set:

arrow keys “▲” and “▼” allow to set a duration between 10 ms and 1,000 msec.

Monitor sorting gate is set either “ACTIVE” or “not active”. If active, then:

- connect a sensor at input „GatePos-i“ which is allowed to give a +24V-signalonly when sorting gate is in NOK position.There is a direct assignment between the sum signals END-i from „resultLOCATION 1-...“ and „GatePos-i“: At END_1, GatePos_1 is used, at END_2,GatePos_2 follows a.s.o.

- the sum sort signal OK-i from result LOCATION 1-... is supplied to control asorting gate.

- the sum end signal END-i from result LOCATION 1-... is supplied to control astopper and in case of NOK-parts delayed as long as the input "GatePos-i"gives a +24V-signal. If delay is more than 1 second a failure message isgenerated and the station stopped.

If monitor sorting gate is set to "not active" monitoring is off.

4.3.3. Inputs and Outputs

The assignment of internal logical signals of the eddyvisor® (Start-1, GatePos-S,etc.) to the physical inputs and outputs of the VCONI takes place.




It is set in test assembly which logical signals are really used. In addition, there aresignals which are always present (e.g. StatActive-1).

It is recommended to work with the standard assignment and to do individualsettings only as an exception.

The inputs and outputs work with 24Vdc-Logik and may be directly connected withswitches, sensors (PNP-type, +24V switching) resp. sorting gates and other loadconsumers. Control of the eddyvisor

®via a PLC is feasible as well.

In order to increase the current load capacity of the outputs several output signals ofone VCONI may be connected with the same logical signal and switched in parallel.

4.3.3.1. Selection of VCONI

All available connectors are sorted according to the slot of the VCONI in the upperline and connector designator A or B; they may be selected by this identification,built of slot number and connector designator. Possible slots of the VCONI are slot3 in desktop instrument model, slots 6 and 7 in switchboard integration model.

4.3.3.2. Monitor inputs, force outputs manually

All input signals are asked every approx. 200 msec. and displayed. "ON" means+24Vdc input voltage. "OFF" means no input voltage.

All outputs may be operated manually to check electrical wiring and function.

Remark:When entering menu all stations must be stopped. Already started measurementsare finished and may be looked at, only then the outputs may be switched manuallyand the set function of inputs and outputs is unassigned until leaving the menu.

Pressing the key "Force Outputs (manual)" releases the outputs for manualoperation after a safety request. The name of the key changes to "DeforceOutputs“.

Attention:If the outputs are manually operated this may affect any connected instruments! Ifseveral outputs of a VCONI are switched in parallel in order to increase current loadcapacity, consider this when manual switching the outputs, danger of short circuit,however, does not exist as the outputs of the VCONI are pure +24Vdc-driver (High-Side Driver).

The released outputs appear as key with name "OFF" for 0V resp. "ON" for +24Vdc.Pressing the key changes the condition of the key and the output. When there is novoltage at the corresponding pin of the connector, the voltage supply of the VCONI-




board has to be checked: The bridge connector has to be put for supply frominternal voltage source or the VCONI has to be supplied externally with +24Vdc.

4.3.3.3. Allow Signal Assignment

Each logical signal can be assigned to a physical input resp. output via the menu"Allow Signal Assignment". Logical input signals may be assigned only to onephysical input. Logical output signals may be assigned to any physical outputs. Afterpressing the key, a safety request appears and the name of the key changes to"Quit Signal Assignment".

It is recommended to work with the standard assignment and to choose otherproposals only as an exception. In very special cases only, an individual setting isnecessary.

Modified assignments of signals are displayed in blue colour. Pressing the key"Discard changes" restores the previous assignments and pressing "Savesettings" takes any changes. When leaving the menu a safety request asks if totake of discard assignments.

Standard Signal assignment

A standard assignment of signals for each constellation of instrument isrecommended. Pressing this key restores this constellation.

Show Proposal

A menu shows different pre-defined connector assignments. Should the standardassignment not cover the case of application, other typical assignments are givenhere. The text right beside the selection field informs on the planned application.Touching the names displays the new assignment with blue changes. Selection hasto be confirmed with key "Load Assignment" or leave the menu with key "DiscardProposal". An overview of all proposals is given in chapter 6.3.1. Proposal forSignal Assignment.

Unassign all Pins

All assignments between logical signals and physical inputs and outputs on thisconnector are unassigned and marked with "---".

Logical Signal Assignment - Selection window

Pressing the keys for logical signals assigned to the inputs and outputs opens awindow "Logical Signal Assignment". There are separate menus for inputs andoutputs. The following signals are available at the moment:




Global signals, inputs

o GlobalSelfCalibOff - Stop automatic calibration.ResetCnt-1 - reservedDisableStart - Stop START-signals.

o PLC-IN - signals for remote control by PLCStrobe-TypeStrobe-MenuStrobe-CmdData-IN-0..7

Signals for structure test, inputs

o Start-SignalsStart-1..32 - start signal for structure test.

o GatePos-SignalsGatePos-1..32, -S - message from sorting gate.

Global signals, outputs

o GlobalReqSelfCalib - message of eddyvisor®: calibration due.Counter-1 - reservedBusy-S - structure test is running.WatchDog - reserved.

o PLC-OUT - signals for remote control by PLC.OUT-TypeOUT-MenuOUT-CmdData-OUT-0..7

Signals of structure test, outputs

o End-SignalsEnd-1..32, -S - test finished

o OK-SignalsOK-1..32, -S - test result OK.

o NOK-SignalsNOK-1..32, -S - test result not OK.




o StatActive-SignalsStatActive-1..8 - station in reference data recording or in PreventiveMulti-Frequency Testing.

unused, unassignment of single signal assignments, symbol “---”.

4.3.4. System Properties

Basic settings like printer, integration of eddyvisor® into a local network anddate/time are managed in menu "System Properties" as well as some statusvariables are shown.

Any changes may be discarded by key "Discard changes" unless they areexplicitly saved by the key "Save settings". When changing menu a safety requestasks if to store or discard changes or cancel change of menu.

Pressing "Standard settings" sets all settings in this menu to standard value. Dateand time are not influenced.

4.3.4.1. Printer setting

Driver (printer language)

Set the language of the printer which is used and with it the printer driver. Thefollowing languages are available:

PS Level 3Suitable for Post Script capable printers.

PCL 6 (Laserjet)Suitable for laser printers which support PCL6

PCL 5C (Laserjet Color)Suitable for colour laser printers which support PCL5

PCL 5 (Laserjet)Suitable for laser printers which support PCL5e

PCL 3 (Laserjet + Deskjet)Suitable for many HP Deskjet printers

HP printers resp. HP (PCL) compatible printers are exclusively supported (exceptfrom PS). The language of the printer can be found under technical data of theprinter.

Attention: HP printers with "LIDL" (Lightweight Imaging Device Interface Language)are not supported.




Interface (USB or TCP/IP)

Selects the interface of used printer. A local printer will be connected via USB, anetwork printer will be connected via Ethernet using TCP/IP.

USB printer type

One USB printer type only is allowed to be connected. The first printer model whichis connected after switching on resp. already connected will be used. Furtherconnected printers are ignored.

TCP/IP Network printer

In case of a network printer (TCP/IP) the IP-address of this network printer must bespecified. A "standard-TCP/IP port" with following settings is used:

- Protocol: Raw- Port number: 9100- SNMP: No

Paper size

Determines the paper size. It may be selected between „letter“ and „(DIN) A4“.

4.3.4.2. Network setting of eddyvisor®

Obtain address, IP-address, Subnet-Mask

Determines where the eddyvisor® gets its network address from. This setting isneeded when the eddyvisor® is connected to a local network.

„DHCP“ (Dynamic Host Configuration Protocol) means that the network addressesare obtained automatically from a DHCP-server. In this case, no further settings arerequired.

If "static" is selected, a valid IP-address in the network and the networks subnet-mask have to be set. Remark: The subnet mask divides the IP-address into aforepart indicating the network and a back part indicating the user-ID.

Host-name of eddyvisor®

The host name of the eddyvisor® in the network is derived from the serial numberof the instrument: e.g. „ev00123“ for eddyvisor

®S/N 00123.

Remark: Many operating systems provide the command "ping" to check the networkconnection. Access to the eddyvisor

®S/N 00123 is tested with „ping ev00123“.




4.3.4.3. Date / Time

Change date and time of internal clock.

Changes are taken immediately.

4.3.4.4. Form

Company's name to be used in printouts.

4.3.4.5. Network-Log

The measuring results of "reference data recording" and "Preventive Multi-Frequency Testing" " or “Preventive Multi-Filter Testing” may be sent continuouslyto a network user. This taking down of measuring results may be switched on andoff.

The target address of log data is given either as hostname or IP-address. Remark:Not every network supports usage of a broadcast-ID.

4.3.4.6. Mouse pointer on/off

A mouse pointer may be faded in for presentations with an external monitor.

4.3.4.7. System monitor

The values of "CPU temperature", "Motherboard temperature", "CPU core voltage"and speed of fan 1 and 2 are displayed for diagnosis of system. These values aremeaningless for operation of eddyvisor®.

4.3.5. Part Type Administration

The standard project includes part type 1 with name "standard" and "part number01", refer to part type field on the eddyvisor® in the upper left-hand side. This menuallows to create and individually name of part types.

The available part types are listed in a table.

Selection key “►” Allows to select a part type.

Type-No.Opens a window with two arrow keys “▲” and “▼” to set the number of part type. Part type 1 cannot be renumbered.




Caption 1Opens a window with a keyboard to type individual descriptions.

Caption 2Opens a window with a keyboard to type individual descriptions.

DateDate when part type was created.

Touching the headlines sorts the list of part types according to the relatingcriterion. Several touching reverts order.

The following actions are available to create and delete part types:

Key "Add new Part Type“Adds a part type to the list at the position with lowest number.

Key "Copy marked Part Type“Copies the selected part type into the list at the position with lowest number.Does not copy reference and sorting data.

Key "Copy marked Part Type with Parts“Copies the selected part type into the list at the position with lowest number.Does also copy reference and sorting data.

Key "Delete Part Type“Deletes selected part type from the list. A different part type is automaticallyselected.

Key "Load in all stations“Loads selected part type to all test stations of the eddyvisor®. Does not leavethe menu.

If part types are set up then the key Part type selection in the upper left-handside of the screen may be used without calling the setup. It also opens the"Overview of saved Part Types", however, the parts may only be sorted andloaded. A selected part type is load into the current resp. all stations with key"Load only in this station" and "Load in all stations" and the menu is left.The key "Cancel" leaves the menu without changes.

4.3.6. Frequencies & Locations (general)

The test procedure of the individual stations and locations is significantlycharacterised by the test frequencies / band passes, settling delay and test time.Menu "Frequencies & Locations" allows to set all part type specific parameters.

When changing menu a safety request asks if to store or discard changes or cancelchange of menu.




4.3.6.1. Activate / deactivate location

A test block of a station usually includes several locations. The eddyvisor® supportstesting of different part types. Often it is the case that a certain part type has to betested at a certain location, another not.

Locations may be excluded resp. included again by pressing the key "DeactivateLOCATION" resp. "Activate LOCATION". Name of key changes accordingly.Deactivated stations and locations are marked grey crossbred in the stations andlocations bar and are not considered at testing.

The information which locations are active resp. inactive for a certain part type issaved with the relating part type.

4.3.6.2. Standard settings

This key resets all settings in this menu to standard settings.

4.3.6.3. Discard changes

This key discards any changes before they were explicitly saved.

4.3.6.4. Save settings

This key saves the setting for the currently selected location(s).

4.3.6.5. Save all settings

This key saves the settings for all stations and locations.

4.3.7. Frequencies and locations (structure test)

4.3.7.1. Tolerance zone shape (ellipse / rectangle)

The eddyvisorS may create both elliptic and rectangular tolerance zones and in

Preventive Multi-Frequency Testing it checks the test results for keeping thetolerance.

Switching between elliptic and rectangular tolerance zone shape is done by thetolerance zone keys A - F for each frequency. Pressing „TOL zone“ changes alltolerance zone shapes at the same time. The selected shape is symbolically shownin the key.




If a tolerance zone in the tolerance zone editor is set to "manual" this condition issymbolically shown as a small hand in the key. If this key is pressed the tolerancezone is set to "automatic" and the manual changes of this tolerance zone get lost.

When all locations of a station are displayed (key below "LOC") the tolerance zoneshape (ellipse or rectangle) of all locations of one station can be changed at thesame time. Tolerance zone shapes differing for all locations are marked withsuperimposed empty symbols.

4.3.7.2. Tolerance zone factor

This factor indicates the enlargement (minimising) of the unified ellipse / unifiedrectangle to the valid tolerance zone. The unified ellipse is the smallest ellipsesurrounding the measuring values. The same is valid for the unified rectangle.

The tolerance zone factor can range between 0.8 to 9.9. Pressing the key „TOLzone Factor“ changes all tolerance zone factors at the same time.

When all locations of a station are displayed the tolerance zone factors of alllocations may be changed at the same time. Tolerance zone factors that are not thesame for all locations are marked with ***.

The tolerance zone factor is used in the same manner for automatically andmanually created tolerance zones.

4.3.7.3. Frequency

The test frequency may be varied in the range of 5.0 Hz to 250 kHz resp. 6.0 Hz to300 kHz - depending on suppressed noise frequency. Up to eight measurings withdifferent frequencies may be set for each location.

When all locations of a station are selected the test frequencies of the locationsmay be changed at the same time. Test frequencies that are not the same for alllocations of a station are marked with ***.

Pressing the key "Standard setting" sets noise suppression for the current locationto Not Active and the suppressed noise frequency 50 Hz. The key "Standardsetting" sets AutoStart function to standard value.

Pressing the key "Suppressed noise frequency" sets a noise frequency to besuppressed either to 50 Hz or 60 Hz. Pressing the key "Noise suppression"prolongs the measuring time of the single tests in order to suppress interferinginfluences due to line frequency. Noise suppression is achieved by prolongation oftest time per frequency to integral multiple of the period of the noise frequency.




Noise suppression does not work at test frequency 50 Hz resp. 60 Hz. If there occurany interferences, these frequencies cannot be used.

Pressing the key "Distribute Frequency" evenly distributes possible test frequenciesto the amount of tests.

The test frequency influences the separation of different test parameter. Theselected frequency ratio (largest to smallest frequency) should be large for hightest reliability. The frequency range must be within the allowed frequency range ofthe connected coil(s) – see coil labels.

4.3.7.4. Test time and settling delay

The test time of a location is determined by settling delay and the following testswith different frequencies. When noise suppression is active, the measuring time ofthe single tests is prolonged in order to suppress negative influences due to linefrequency.

The lower side of the screen shows the test time for the selected location and thetotal test time for all locations of the station.

The time between appearance of START-signal and start of the actual test is set bykey "Settling delay" between 0 and 5,000 msec. It guarantees that the newarriving test part has enough time to position well in the test coil.

A too short settling delay increases the scattering values of testing at external Start-signal and AutoStart. A too long settling delay reduces throughput.

For locations with start triggering AFTER, it has to be checked if a delay time afterthe preceding test is necessary. If not, settling delay should be set to 0 msec inorder to keep the total test time as short as possible.

4.3.7.5. AUTOSTART Configuration

The eddyvisorS supports automatic parts recognition in coils and thus start

triggering for any locations. It must be selected as "AutoStart" in test assembly forthe relating locations. "AutoStart" function works with a frequency fed to the test coilfor parts recognition and is set for each location separately:

AutoStart Frequency

In mode AutoStart, the AutoStart frequency is quasi permanently present to thecoils for which AutoStart is set between the single tests.

The AutoStart frequency should not be too low in order to avoid heating of coil.




AutoStart recognises approaching of test part to coil by means of AutoStartfrequency.

An AutoStart frequency of approx. 2/3 of the selected test frequency range issensible for most applications.

Threshold

If the delta value d reaches the threshold (e.g. 3,000) the AutoStart condition isfulfilled. If the eddyvisorS is in mode reference data recording or Preventive

Multi-Frequency Test this would trigger the start of this location.

Thus the threshold must be exceeded when a test part approaches the coil in orderto trigger a test.

If the threshold is set close to the max. occurring delta value the test is triggeredjust before the final location of the test part. A practical value is approx. 75 % of themax. delta value.

The threshold is adjustable with the visible arrow keys in the range of 250 up to11,500.

x/y coordinates

The AutoStart frequency is quasi permanently present at the test coils of a location,the x/y coordinates of the AutoStart frequency are noticed and displayed.

At an empty coil this can be e.g. x = 9,500 and y = 5,300.

When the test part approaches the coil these values change considerably.

u/v coordinates

The x/y coordinates are stored in u/v by pressing the key „accept u/v“. This key hasto be pressed at empty coil.

Delta-value d

The delta value d is the distance between the value stored in u/v and the current x/yvalue.

The AutoStart is not securely triggered when the delta value is too low (perhapsselect different AutoStart frequency).

The d displays if the coil voltage with test part (x/y) supplies a delta value highenough compared with the empty coil (u/v).




u/v values are free / fix

If this value is free the coil must be empty when activating the eddyvisorS in

mode reference data recording or Preventive Multi-Frequency Test. TheeddyvisorS determines the u/v values anew every time when activating

reference data recording or Preventive Multi-Frequency Test.

If this is the case, the test is - as required - triggered with full coil (test part in testcoil).

If this is not the case, the test is triggered at empty coil which results in faultytriggering.

In mode u/v values are fix, the u/v values in the eddyvisorS are NOT

determined anew when switching to mode reference data recording resp.Preventive Multi-Frequency Test, they are quasi "frozen".

The coil may now be "filled" when changing to an active mode, aforementionedfaulty triggering will NOT occur.

Remark:The key "Default settings" resets the AutoStart function to standard value.

4.3.8. Frequencies and locations (crack detection)

4.3.8.1. Band pass and tolerance zone

The eddyvisorC is capable of evaluating the signal of a crack detection probe at

the same time in 30 band passes. The mentioned band pass frequency is its centrefrequency.

Each band pass may be activated or deactivated at request by touching thefrequency. A deactivated band pass is furthermore shown palely, however does notinfluence the result.

Each band pass has its own tolerance zone. There are three setting possibilities foreach of the 30 band passes.

kind of tolerance zone creation (not implemented)

tolerance zone factor amplitude

tolerance zone factor angle




4.3.8.2. Tolerance zone factor

The total of all polar fields of the reference data for one band pass results in a"wrapping" polar field. This polar field may be widened in amplitude and in angle inorder to create the tolerance zone for testing.

The left figure is the factor for the amplitude by which the tolerance zone iswidened. The right figure is the angle by which the tolerance zone is widened.

4.3.8.3. Sender frequency

The frequency for the sender winding of the probe is determined. The acceptablefrequency range of the probe has to be considered.

4.3.8.4. Tolerance zone factors commonly operated

If this is selected, the tolerance zone factors (amplitude and angle) for all 30tolerance zones are modified at the same time. This the basic setting.

In special cases only, it is sensible to select different values. Attention: This settingacts also to the direct shifting of tolerance zone factors in reference data menu.

4.3.8.5. Threshold

Two thresholds are available. The first threshold is always lower than the secondone. The relating warn-output is activated when the separation figure exceeds thestated threshold. The threshold does not influence the actual sorting result.It can be changed in 5 % steps.

4.3.8.6. Settling delay

The time between appearance of START-signal and start of the actual test is set bykey "Settling delay" between 0 and 5,000 msec.

As this is rather unusual at crack detection the standard setting is 0 ms.

4.3.8.7. End of test after …

End of test after end of start signal

As long as the set start signal is active testing runs (exception: settling delay). Assoon as the start signal is inactive testing ends.




End of test after time period

Testing ends automatically after a pre-selected time.ATTENTION: This time is also kept when changing from reference data or sortinginto the setup menu.

End of test after xxx revolutions

Test ends automatically after a pre-selected amount of revolutions.ATTENTION: It is stopped only when the amount of revolutions is finished. In orderto guarantee proper function, also when trigger is missing (stopped lathe), thisfunction is only allowed in combination with speed monitoring. If speed is fallenbelow the set limit, testing is finished and the part is marked as "bad".

End of test after lift-off

Test ends automatically when the maximum allowable distance is achieved.

4.3.8.8. Lift-off compensation monitoring

If a crack detection probe with lift-off compensation is used the allowable distancecan be monitored. If distance exceeds the range of lift-off compensation (2.0) thetest part is marked as "bad".

The value of the maximum allowable distance can be decreased here. Test systemsmay be monitored which work with very narrow tolerances.

If lift-off compensation is not required it can be deactivated.

4.3.8.9. Monitoring of probe (noise threshold)

The noise threshold recognises if at least in one band pass the valid tolerance zoneis achieved with the set percentage. This enables detection of probe defects likeshort circuit or break but also mechanical defects like probe is not near part or partis not rotating.

4.3.8.10. Speed monitoring

Speed monitoring guarantees that the part does not rotate too slowly or too fastduring testing. At least two trigger impulses must be recognised.

If speed monitoring is not required it can be deactivated (off).




4.3.8.11. Frequency range proposals

Selection of range of band pass:

20 kHz - 25 Hz (only for very high surface speeds)

10 kHz - 12 Hz standard

5 kHz - 6 Hz (only for very slow surface speeds)

4.3.8.12. Setup Lift-off compensation

A menu for setting of lift-off compensation opens. This setting is imperativelynecessary when the probe is exchanged or the length of the probe cables ischanged.

At big differences in material, new setting can be necessary. For this case, settingcan be done part type specifically.

Put probe in air (without part)

The operator confirms by pressing this key that no part is near the probe. Thedistance should be more than 5 mm.

Put standard distance (0.7 mm)

The operator confirms by pressing this key that the probe - part - distance is atstandard. The standard distance is 0.7 mm. When using special probes or due tomechanical reasons (in tight limits) another distance than 0.7 mm may bedetermined.

4.4. Reference Data

In mode reference data, OK parts are read and the tolerance zones are created.The data are the basis for the sorting decision in mode Preventive Multi-Frequency /Multi-Filter Test.

A station in mode reference data recording is running when a yellow triangle in theupper left-hand corner of the station bar is on.

The recorded reference data can be displayed differently, refer to point "4.6. Displayoptions" from page 4-26.




4.4.1. Data recording active

Pressing the key "Activate data recording" activates stations to the status referencedata recording runs and the description of the key changes to "Data recordingactive".

The first activated location of the station is sensitive for incoming start signals. Assoon as it is started, in general all other activated locations are also sensitive forstart signals.

Touching the START-key triggers measuring at the current station and location,independently from set start signal. Structure test, the test stops after the test timeitself. Crack test, the test is ended by pressing the STOP-key.

Locations connected with AFTER: the eddyvisor® starts the next measuring, notconnected with AFTER and thus triggers all measurings connected with AFTER.

4.4.2. Data recording stopped

Pressing the key "Data recording deactivate" sets stations to the status referencedata recording STOPPED and the description of the key changes to "Data recordingstopped".

Recording of reference parts is finished, still missing locations are markedaccordingly. This can be seen by selection of the relating location: a question markis shown instead of position of selected measuring in the tolerance zones.

4.4.2.1. Navigation in parts

Two arrows appear in the lower right-hand corner in mode reference data recordingstopped. These two arrows serve as navigator within the reference parts. Themeasuring data of the single locations are accessible with location keys, notrecorded locations are displayed in the tolerance zones as question mark.

A reference parts history is positioned down left, one stroke per reference part.Usually all strokes are green and a white arrow indicates the selected part. Notcompletely recorded parts are stroked grey. Marked reference part are red. Theheight of the strokes means the position of reference data regarding the tolerancezones.

A parts counter is downright beside the history. It shows the number of selectedparts, the amount of recorded and marked reference parts. Furthermore, the validityof the selected part and the time stamp of data recording are displayed.




Touching the parts counter toggles between amount of all reference parts andamount of marked parts and thus navigation between all parts and marked parts istoggled.

For further hints refer to point "4.6.3. Parts counter and history" from page 4-31.

4.4.2.2. Mark reference parts

In mode reference data recording stopped individual reference parts may bemarked and so excluded from creating tolerance zones.

Reference parts are marked by key "Mark Reference Part" resp. "UnmarkReference Part " and so excluded from creating tolerance zone resp. again be usedfor tolerance zone creation. The text of the key changes accordingly.

The key "Delete Reference Data of this STATION" deletes all data after a safetyrequest.

The key "Delete all marked parts" deletes all marked reference parts without safetyrequest.

4.4.2.3. Tolerance Zone Editor (structure test)

It might be necessary, in special cases, to modify a tolerance zone manually.

By pressing the key "Tolerance Zone Editor" the tolerance zone changes to a yellowheadline with the name "Tolerance zone editor". The following keys appear:

Tolerance zone factor - enables scaling by a factor to be set between 0.8 and9.9.

Ellipse / Rectangle - changing the shape of the tolerance zone between ellipseand rectangle.

Tolerance zone manual - after a safety request, further keys appear whichenable free selectable position of the ellipse in the space independently from thereference data. This function should be applied by specially trained personnelonly. Manually modified tolerance zones are marked accordingly. The key"Tolerance zone automatic" cancels the manual setting of the tolerance zone.

Undo - discards any changes since latest access of the tolerance zone editor.The tolerance zone editor is not left.

Exit tolerance zone editor - after a safety request, the tolerance zone editor isleft with resp. without acceptation of changes.




4.5. PMFT - Preventive Multi-Frequency / Multi-Filter Test

In mode Preventive Multi-Frequency Test, parts are tested and classified as OK orNOK part depending the tolerance zones.

A station in mode test is running shows this by a green triangle in the upper right-hand corner of the station key.

The recorded sorting data may be displayed differently, refer to point "4.6. Displayoptions" from page 4-26.

4.5.1. Testing active

By pressing the key "Activate Testing" stations are set to status testing and thedescription of the key changes to "PMFTesting active".

The first activated location of the station is sensitive for incoming start signals. Assoon as it is started, all other activated locations are sensitive for start signals.Structure test, the test stops after the test time itself. Crack test, the test is ended bypressing the STOP-key.

Touching the START-key triggers measuring at the current station and location,independently from set start signal. Structure test, the test stops after the test timeitself. Crack test, the test is ended by pressing the STOP-key.

Locations connected with AFTER: the eddyvisor®

starts the next measuring, notconnected with AFTER and thus triggers all measurings connected with AFTER.

The function of the parts counter is explained in the following chapter.

4.5.2. Stop testing

Pressing the key "Stop Testing" all stations are stopped and the description of thekey changes to "Testing stopped".

Recording of test parts is finished, still missing locations are marked accordingly.This is visible by selecting the relating locations. A question mark is visible in thetolerance zone instead of the position of the selected measuring.

A yellow field with two arrow keys appears in the lower left-hand side of the touchscreen. Pressing these arrows switches between the test parts.




4.5.2.1. Navigation in parts

In mode testing stopped, two arrow keys appear in the lower right-hand corner ofthe screen. The arrows allow to toggle between reference parts. The measuringdata of the single locations are accessible by location keys, not recorded locationsappear as question mark in the tolerance zones.

A test parts history with a stroke per test part is placed on the lower left-hand side.Good parts create a green, bad parts a red stroke. Incompletely recorded parts aregrey strokes. Parts which were tested before a change of test conditions (change oftolerance zone or similar) have a yellow shade. A white arrow indicates the selectedpart.

The height of the strokes means the position of measuring data regarding to thetolerance zones. The largest relative distance to the tolerance zone is displayedover all angle steps.


4.5.2.2. Parts Counter

The parts counters are placed at the lower right-hand side beside the history. Theyshow the number of the selected part, the amount of tested parts and the OK- andNOK-sorted parts. Furthermore the time stamp of testing is shown.

Touching the parts counter shifts between amount of all test parts, amount of NOKparts and amount of OK parts and thus navigation between all test parts, NOK partsand OK parts is switched.

At running test, the parts counter shows the amount of recorded parts and isautomatically increased. The sum of OK parts and NOK parts is displayed asabsolute figure and as percentage in relation to sum of test parts.

The key "Reset Parts Counter" resets the counter for test parts, OK parts andNOK parts to 0 and deletes parts history.


4.5.2.3. Screen off

The screen may be switched off by pressing this key. This extends the life time ofthe TFT backlight. By touching the touch screen at any point it comes up again.




4.5.2.4. Add test part to Reference Data

Pressing key “Add test part to Ref.-Data” adds data of the selected test part to thereference data, the tolerance zones of all locations are calculated anew.

Due to the new tolerance zones the tolerance zone distance of already tested partschanges as well. The parts which are tested and sorted with old tolerance zones aretherefore displayed with a yellow shade on the parts history.

4.5.2.5. Tolerance Zone Editor (structure test)

In special cases, it can be necessary to change a tolerance zone manually. The key"Tolerance Zone Editor" enables manual access to tolerance zones without priorswitching to mode reference data recording.

For further hints refer to point "4.4.2.3. Tolerance Zone Editor (structure test)" frompage 4-23.

4.6. Display options

4.6.1. Structure test

Several options are available to display the test results. Standard is: Locus curvedisplay in "reference data" and bargraph display in "Preventive Multi-FrequencyTest".

4.6.1.1. Locus curve display

This display refers to one position of one station.

The results of all test frequencies are displayed at the same time in a common x/ycoordinate system, thus the name locus curve display. All tolerance zones of oneposition as well as the measuring points are displayed in one common screen area.

By touching the key "Show TOLzone labels", the letters of the test frequenciesA - H are shown.

By touching the screen area, it is switched to tolerance zone display - all.

4.6.1.2. Tolerance zone display - single

A single tolerance zone of one position is displayed.




The tolerance zone as well as measuring points are displayed in one common x/ycoordinate system.

By touching the screen area, it is switched to tolerance zone display - all.

4.6.1.3. Tolerance zone display - all

This display refers to one position of one station. All tolerance zones of one positionare displayed at the same time.

An x/y coordinate system with tolerance zone and measuring points is displayed foreach frequency.

The tolerance zones - headlines or keys - are named as follows (from left to right):

- station and location 1.1 - 8.32 if needed- test frequency letter A - H- tolerance zone factor 0.8 - 9.9- scale for tolerance zone 100 mV - 20.0 V- test frequency 5.0 Hz - 250 kHz resp. 6.0 Hz - 300 kHz

By touching the screen area of a tolerance zone, it is switched to tolerance zonedisplay - single.

4.6.1.4. Bargraph display

Bargraph display is available for Preventive Multi-Frequency Test only. Followingversions exist:

as overview of all stations;with parts counter, sorting result and small bargraph diagrams of all locations.Touching the bargraph diagram of a station switches to the overview of thestation.

as overview of all locations of one station;with bargraph diagram of one critical frequency to each location. Touching thebargraph diagram of a location switches to the overview of the location.

as bargraph diagram of each frequency of one location - classic display;with setup data and small tolerance zone of each frequency. Touching thebargraph diagram switches to locus curve display.

The distances of the measured part to the relating tolerance zone are displayed asbargraph. A green bargraph signals that the part is within the tolerance zone at thatfrequency. A red bargraph signals that the part is outside and therefore a bad part.




Right beside the bargraph, the relative distance to the edge of the tolerance zone isnumerically displayed.

4.6.2. Crack detection

Several options are available to display the test results. Standard is: xyt-display(one tolerance zone) in "reference data" and bargraph display in "Preventive Multi-Filter Test".

4.6.2.1. Outline bars

30 small bargraphs are displayed on the left-hand side for all test data displayoptions.

Each bargraph is inscribed with the centre frequency of the band pass and posesthe largest achieved distance value for a band pass. The distance value (separationfigure) arises from the comparison of test signal and tolerance zone of this bandpass. That value is displayed where the signal is closest to the tolerance zone resp.it exceeds at the most.

When the bargraph reaches the centre line then the tolerance zone is just reached(distance resp. separation figure = 1). Values 1 are "good" (green) and values 1are "bad" (red); like at structure test.

While a part is tested the present value (live) is displayed as inner, filled bargraph.The maximum value for this test part since start of test is displayed as outerbargraph (outline bar).

Bargraph for probe distance (lift-off)

If lift-off compensation is used, an extra bargraph is shown under the outlinebargraph indicating probe distance.

The centre line of this bargraph is standard distance. The left limitation is close tothe part (gain correction -6 dB), the right limitation is far away from the part (gaincorrection + 6 dB). As long as the probe distance stays within this limitation thesignal is lift-off compensated.

While a part is tested the present value (live) is displayed as inner, filled bargraph.The minimum and maximum value for this test part since start of test are displayedas outer bargraph (outline bar).

Sender frequency

The sender frequency is displayed above the outline bargraph.




The sender frequency may be changed in "Setup" / "Frequencies & Locations" butalso in menu "Reference Data" provided that data recording is stopped.

4.6.2.2. Tolerance zone display - single (xyt-display)

A single tolerance zone (a single band pass) of one location is displayed. Thescrollbar beside the outline bar enables selection of the tolerance zone (band pass)to be displayed.

By touching the screen area of the x/y- or xy(t)-display, it is switched to tolerancezone display - all.

x/y-display

The tolerance zone (green), the polar field of the selected test part (orange) andwhen testing activated also the live-signal (white) are displayed in one common x/y-coordinate system.

y(t)- and x(t)-display

The live-signal is shown on a time axis. It is very recommended to use a triggersignal (one impulse per revolution) for a sensible display. The trigger point isleftmost on the time axis.

The time axis is automatically scaled to exact two revolutions (different fromoscilloscope) as far as trigger signals are available. This enables an allocation ofposition of crack to rotation angle.

Further elements

Scaling of display in mV /div (zoom)

The largest value of a tolerance zone is always 1 V amplitude due to automaticsetting of gain. This corresponds to 500 mV / div two small boxes in standardsetting. The display is so most often sensibly scaled.

The display can be "zoomed" by means of manual selection of a different scaling.This enables visualisation of very small or very big signal portions.

This scaling refers to x/y-, y(t)- and x(t)-display, however, does not influence thetest.

Tolerance zone factor




The total of all polar fields of the reference data for one band pass results in a"wrapping" polar field. This polar field may be widened in amplitude and in angle inorder to create the tolerance zone for testing.

The left figure is the factor for the amplitude by which the tolerance zone iswidened. The right figure is the angle by which the tolerance zone is widened.

Amplification

The necessary amplification is automatically calculated from the tolerance zone. Bythis, the tolerance zone is standardised to the maximum amplitude of 1 V.

With an amplification of 100 dB, e.g., an input signal of 10 µV is amplified by 100 dB(multiplied with 100,000) and so displayed with 1 V amplitude on the screen.

The amplification may be indirectly changed by changing the tolerance zone factor -amplitude (the first value). When the tolerance zone factor is doubled, thenecessary amplification is only half as big. It reduces by 6 dB. When the tolerancezone factors are operated commonly, the amplification for all band passes can bechanged at the same time although the band passes uses different amplifications.

Speed

While a part is tested the present value of the speed is displayed. After end of testthe minimum and maximum speed is displayed occurred during the test.

4.6.2.3. Tolerance zone display - all

All tolerance zones (green) and all polar fields of the selected test part (orange aredisplaced at the same time. Each of the 30 small x/y-coordinate systemsadditionally show the centre frequency of the band pass and the amplification.

The display option is suitable to get a quick overview of signals generated by thetest part. Here, at one glance, all amplification factors can be checked and the"roundness" resp. the shape of the polar fields can be assessed.

Touching the screen area of a not yet selected tolerance zone, it is selected. Onlyfor the selected tolerance zone, also the live-signal (white) is displayed when testingis activated.

Touching the screen area of an already selected tolerance zone, it is switched totolerance zone display - single.




4.6.2.4. C-scan display

Here, the reeling off of the test part three-dimensionally (as waterfall) is displayed.Each revolution supplies a "line", each line starts on the left with the trigger. Thelive-signal of the selected band pass is displayed, standardised to the tolerancezone.

4.6.2.5. Bargraph display

Bargraph display is only available in Preventive Multi-Filter Testing.

A cut-out of 9 bars out of the 30 small bars is displayed enlarged. The cut-out canbe selected by the scrollbar.

Each bar is inscribed with tolerance zone factor, amplification and centre frequencyof the band pass and poses the largest achieved distance value for a band pass.The distance value (separation figure) arises from the comparison of the test signalwith the tolerance zone of this band pass. That value is displayed where the signalis closest to the tolerance zone resp. it exceeds at the most.

A green bar signals that the part with this band pass is within the tolerance zone. Ared bar means that the part is outside and thus "bad". Right beside the bargraph,the relative distance to the edge of the tolerance zone is numerically displayed.

While a part is tested, the present value (live) is displayed as inner, filled bargraph.The maximum value for this test part since start of test is displayed as outerbargraph (outline bar).

In addition, the largest of all 30 bargraphs is separately displayed.

4.6.3. Parts counter and history

The parts counter (downright) show - at running test - the latest tested part and sothe amount of tested part. At sorting data, additionally the amount of good and badparts and the percentage is displayed. At reference data, additionally the amount ofmarked parts is displayed.

At stopped test, the parts counters show the number of the just selected part. Thetotal amount of parts is now displayed as "of xxx parts". Two navigation keys appeardownright to browse between the parts.

Under the parts counter the time stamp of the test is shown for each part.

Down left, the history is shown. Each new part creates a small stroke on the right-hand side of the history and all older strokes move to the left. The height of thestroke indicates the distance to the tolerance zone.




Good parts create a green, bad parts a red stroke. Incompletely tested parts appearas grey stroke. Parts which were tested before a change of test conditions (changeof tolerance zone or similar) have a yellow shade.

When test is stopped a white arrow emphasises the just displayed part in thehistory. Two navigation keys appear downright to browse between the parts.

Reference data are always visible in history.

In sorting data, the history may date back further although only max. 300 parts atonce can be displayed. Depending on the amount of used locations up to 1,000parts can be stored.

Left beside the normal history, an additional bad parts history for 100 bad parts isimplemented. When the storage of the normal history is full the oldest part isdeleted only when it was a good one. If it was a bad part it is moved to the bad partshistory. This enables that data of bad parts can be viewed even then if a lot of goodparts have been tested afterwards. These bad parts keep their number and timestamp, so the history can be helpful with only a few bad parts and long automaticoperation.

Touching the parts counter determines which parts are browsed, this easesbrowsing in the history. In standard case, all parts are browsed. It is also possible tobrowse bad parts only. This is helpful when only a few bad parts are strewed withinthe history.

4.7. Key switch - authorisation level

The key switch allows to switch the eddyvisor®

on and off as well as to protect theeddyvisor® from unauthorised or unintended operation.

During normal operation it is - for safety reason - not possible to modify any settingof the eddyvisor®. Modification of test assembly or allocation of inputs and outputswill have wide consequences and are usually necessary only when installing the testinstrument and case of application.

The positions of the key switch are as follows:

Key switch horizontal lefteddyvisor® is off.

Key switch verticaleddyvisor® is on and authorisation level is standard.

Key switch horizontal righteddyvisor® is on; when turning key switch into horizontal right positionauthorisation level is requested and stored.




The individual authorisation levels are as follow:

o Basic levelAll functions of the eddyvisor® are free.

o Standard (key vertical)Access only via vertical key switch.In addition to authorisation level "reference data", the menus "Project &Language“ to save and call projects, "System Settings", "Part type" and"Frequencies & Locations" are free in setup.

o Reference dataIn addition to authorisation level "Part Types", reference parts may berecorded and tolerance zones edited. Part types may be generated anddeleted.

o Selection of part typeIn addition to authorisation level "test mode", part types may be selected.

o Test modeThe Preventive Multi-Frequency Test can be stopped and started, theSTART-key is active, parts counters can be reset.Setup settings, reference data and tolerance zones may be seen but notchanged.

o None (Total lock)Touch panel ignores user commands.

The key switch may be drawn at any position. In case of power failure or switchingoff the eddyvisor® by external mains plug, the switching off condition is restoredafter switching on the instrument again.

Hint: If the following message appears during operation of the eddyvisor®

Insufficient Authorization Level

the requested action is locked by the key switch. The action has to be released bythe key switch.




5. Data recording via network with eddyLogger

At present, this function is implemented for structure test only.

The measuring results of "reference data recording" and "Preventive Multi-Frequency-Testing" may be sent continuously to a network user. This taking downof measuring results is set in menu "Setup / System Settings".

The program „eddyLogger“ is available for accepting the data. It enables recordingof measuring results of several eddyvisor

®instruments in plain text in .csv files

which may be handled by usual spreadsheet programs like e.g. Excel.

In the field „New File every ..." is set: start a new log-file after a certain amount ofentries or after a certain time period. Too large files are avoided.

In the field „Status“ is shown:

„Started:“ Date and time of program call,

„Logs Started:“ amount of totally created log files,




„Received:“ amount of received measuring results (single measuring and testresult for all parts).

„Lost:“ amount of obviously lost measuring results. The eddyvisor®

transmitsthe data with a consecutive number.

In the field „Log Folder“ the index is shown where the log files are stored. Pressing„...“ opens an index structure for alternative selection. Does the index not exist whenstart logging or are writing rights missing, an alarm message appears.

Logging may be set either to „All Instruments“ or „Specified Instruments“.„All Instruments“ means that the measuring results of all eddyvisor

®instruments

are entered in one log file.„Specified Instruments“ means that the serial number of the eddyvisor® instrumentare given as five digits and logging is started individually.

In the field „Log“ is shown which logging is now active.

The key „Stop All and Exit“ finishes the program after a safety request and savesthe settings.

File name and log file have the following format:

„All Instruments“ mode:„EVLog_“ + „SNxxxxx“ + date + time + „.csv“e.g. “EVLog_SNxxxxx_2006-04-04__12_12_59.csv“

„Specified Instruments“ mode:„EVLog_“ + S/N of eddyvisor® + date + time + „.csv“e.g. “EVLog_SNxxxxx_2006-04-04__12_12_59.csv“

The log files have the following format:

03.04.0614:08

LOG STARTED

Instrument Timestamp PartType

PartNo

Mode Station Position Result FrqA

x y Dist ... FrqH

x y Dist

S/N: 0010303.04.06

13:11 1 11 REFERENCE 1 1 ok25.0Hz 0 0 100

... 25.0kHz 0 0 100

S/N: 0010303.04.06

13:111 11 REFERENCE 1 2 ok

25.0Hz

0 0 100... 25.0

kHz0 0 100

S/N: 00103 03.04.0613:11

1 11 REFERENCE 1 SUM OK

S/N: 0010303.04.06

13:11 1 1 TESTING 1 1 ok25.0Hz 0 0 0

... 25.0kHz 0 0 0,06

S/N: 0010303.04.06

13:11 1 1 TESTING 1 2 ok25.0Hz 0 0 0

... 25.0kHz 1 0 0

S/N: 00103 03.04.0613:11

1 1 TESTING 1 SUM OK

S/N: 00103 -15 LostMessage

S/N: 0010303.04.06

15:48 1 1 REFERENCE 2 1 ok25.0Hz 0 0 100 ...

25.0kHz 0 0 100

S/N: 00103 03.04.0615:48

1 1 REFERENCE 2 SUM OK




S/N: 00123 03.04.0615:50

1 2 REFERENCE 1 1 ok 250Hz

0 0 100 ...

03.04.0617:31 LOG STOPPED

The first and the last line include date and time at the beginning resp. at the end oflogging in this file.

The measuring results of a test location are entered with S/N of eddyvisor®, dateand time of measuring, part type no., part no. with regard to reference datarecording resp. Preventive Multi-Frequency Testing, station no., location no. resp.note of sum result (always „OK“ at reference data) and detailed information on settest frequency.




6. Connection with automatic sort systems

6.1. Automatic test, program course

Integration of eddyvisor®

into automatic test systems may be performed easily asall handshake signals required are already available

An example flow chart is shown hereunder. The test part is transportedautomatically into the test coil, test is started with external START-1 signal, test endis indicated using END-1, and depending on sorting decision OK-1 the part istransported further.

no

noIspart ready for

test?

START-1 creation impulseto trigger

test

transport test partto OK channel

END-1 = 1 ?

END-1 = 0 ?

OK-1 = 1 ?

test parttransported?

yes

no

yes

yes

yes

yes

no

no

yes

no

transport test partto NG channel

test parttransported?

yes

no

correct moderesp. remedy fault

failure message„wrong mode or

failure of eddyvisor®“

START-1control time

ended

signal of eddyvisor®:

START-1 input "start of test 1“END-1 output "test 1 finished“OK-1 sort output "part 1 OK“

example:

Course of program ofan automatic test




6.2. Time diagram

tson

START-1

BUSY-S

END-1

OK-1Zeit

tsoff

tpausetbon

OK-1

OK-1SYNC2

SYNC1

tok

tend

tboff

min. typ. max.

tson 2.5 - - ms

tsoff 2.5 - - ms

tbon 0.5 - 2.8 ms

tboff - 1.0 - ms

tpause 0 - - ms

tend 10 - 1000 ms

tok 10 - 1000 ms

tson, tsoff: time for high resp. low signal of START

tbon: reaction time of eddyvisor® to Start-signal without consideringself-calibration, at release of start

tboff: off-delay of the Busy-signal

tpause: time for pause between consecutive measurements

tend, tok: time interval to be set for END- and Sort- (OK-, NOK-) signals.

synchronous sort impulse length:

SYNC1: sort outputs (OK/NOK/OKS/NGS) are switched off when nextstart signal arrives




SYNC2: sort outputs (OK/NOK/OKS/NGS) are switched off just beforethe next sort decision




6.3. Electronic diagram of interfaces

VCONI-connector A, B

5k4

E+24V

EGND

D-Sub 37

16 inputsmax. 30V

16 outputsà max. 0.6A

1

2

3

4

5

6

7

8

9

10

11

12

13

14

15

16

17

18

19

31

32

33

34

35

36

37

21

22

23

24

25

26

27

28

29

30

20

5k4

Outputs of the VCONI may be switched in parallel in order to increase current load capacity(max. 4 outputs recommended).

4 11 - GND2 - +24V3 - E+24V4 - EGND

Phoenix RM5,08fürFKCVW 2,5/4-STF-5,08

VCONI-connector C




Pin 1 and 2 are connected with a 24 Vdc power supply of the eddyvisor®, current load ismax. 2.5 A. The following pins have to be used with this power supply: Pin 1 with Pin 4; Pin 2with Pin 3. Also refer to "6.4.1. Current supply for in and outputs" page 6-7.




6.3.1. Proposal for Signal Assignment

It is recommended to work with the standard assignment and to choose otherproposals only as an exception.

eddyvisorSStandard allocation

VCONI 3B/6BVCONI 3A/6A




6.4. Example Opto-Interface

6.4.1. Current supply for in and outputs

4

C

3

24GND +24V

2

E+24V

1

EGND

4

C

3

24GND +24V

eddyvisor® VCONI

+24Vmax.2.5A

2

E+24V

1

EGND

10

E+24V

28

9

EGND

37

19 10

28

9

37

19

B A

extern +24V

extern GND

a) <-- supply 24Vdc

ext.+24V

ext.GND

--> I/O-module

ext.+24V

ext.GND

--> I/O-module

2x 4mm²

b) internal 24Vdc power supply

Current supply of output drives of the VCONI-board is done via connector C, pin 1and 2. Basically, 24 Vdc supply is from an external power supply, refer to a) in thefigure. At low load, the internal 24 Vdc power supply of the measuring unit may beused as well, refer to b) in the figure. The max. load of the internal 24 Vdc powersupply is 2.5 A. It has an electronic overload fuse and is available for all VCONI-boards.

The 24 Vdc pin of connectors A and B may be used as current supply of singlesensors or IO modules with low load.




6.4.2. Interface for universal sorting device

1 10

2831

E+24VSTART-1

EGNDOK-S

8

GATEPOS-S

END-S

coil

gate stopper

1

2

A2

A1

A2

A1

SRT STOP

1

2

sorting device

Start-button

M

PNP

+S1

brbl

sw

19 3713 32 35 17 36

9

EGND

plug C

E+24V

EGND

eddyvisor® VCONIconnector A

T1

The figure shows the connection for an universal sorting device to a VCONI-board,connector A. Several outputs are connected with the same signals and switched inparallel in order to increase the current load capacity.

Start key T1 starts measuring via an input assigned to signal START-1. Outputsconnected with signal OK-S and END-S control the gate and the stopper of thesorting device.

Set “Sort Gate Monitor is ACTIVE” to monitor the gate position via sensor S1.




6.4.3. Test on consecutive locations controlled by PLC

- 10

28

E+24VSTART-1

EGNDOK-1

-

START-11

END-1

19 37-

9

EGND

plug C

E+24V

EGND

eddyvisor® VCONIconnector A / B

END-11 OK-11 STATACTIVE-1

-----

MPLC digital input 24V DC

E X.0 E X.1 E X.2 E X.3 E X.4 E X.5 E X.6 E X.7

extern 0V

A X.0 A X.1 A X.2 A X.3 A X.4 M

L+PLC digital output 24V DC

Signal START-1 triggers first measurement, signal START-2 triggers the remainingmeasurement.

EDN-1 quits each measuring. END-S quits the end of sequence of measurementas sum signal.

OK-1 gives the result of each single measurement. OK-S gives the total result assum signal.

StatActive-1 informs station 1 ready for measuring.




6.4.4. Part type switching controlled by PLC

- 10

28

E+24VSTROBETYPE

EGND

-

DATAIN-0

OUTTYPE

19 37

9

EGND

plug C

E+24V

EGND

eddyvisor® VCONIconnector A / B

DATAOUT-0

----

MPLC digital input 24V DC

E X.0 E X.1 E X.2 E X.3 E X.4 E X.5 E X.6 E X.7

extern 0V

A X.0 A X.1 A X.2 A X.3 A X.4 M

L+PLC digital output 24V DC

-

DATAIN-1

-

DATAIN-2

DATAOUT-1

DATAOUT-2

BUSY-S

-

Assignment of signal is done in menu "Setup" / "In- and Outputs". Use of signals isdone in menu "Setup" / "Test Assembly" according to description. The 8 signalsData-In-7..0 and Data-Out-7..0 enable switching between max. 255 part types. Thelimitation to 3 data lines in the example results in a switching possibility betweenmax. 7 part types - not wired signals Data-In-7..0 have status "0".

Signal Strobe-Type triggers switching to part type set on Data-In-0..7. At Data-In-7..0 = 0 a request of the set part type appears.

Signal Out-Type is the handshake signal to Strobe-Type. The signals Data-Out-7..0mirror Data-In-7..0 resp. give the set part type. After successful switching thesignals Out-Type and Data-Out-7..0 merge to status "0".

Part type switching is done for all stations at the same time.




6.5. Coil connection VCONS (structure test)

AmphenolECTA 1332E,12pole jack

A

B

C

D E F

G

H

J

K

L M

Tx+

Tx-

Rx+

Rx-

GND,shield

Tx+

Tx-

Rx+

Rx-

GND,shield

coil 1 coil 2

T+T-

button

Figure: coil connection plug on VCONS-board, structure test

The boards VCONS-02, -04, -06 and -08 have 1, 2, 3, resp. 4 coil connection plugsfor each two coils. The figure shows the 12-pole jack of the VCONS-board and awiring proposal to sender coils Tx, the receiver coils Rx and to the optional testkey T.

Rx+

Rx-

GND,shield

Tx+

Tx-

coil plugto Y-adapter

A

BC

D

E

F

AmphenolECTA 1332E(6pole jack)

Figure: coil connection plug to Y-adapter, structure test

Y-adapters are available to split the 12pole coil connection to the single test coils.They have a 12pole connection directly to VCONS-boards and several 6pole jacksto connect single coils.




7. Part type switching via PLC (structure test)

The eddyvisor® is prepared via the opto-interface for testing the current part type.Switching is effected for all stations at the same time. Part type switching via PLCand request of current part type are described.

7.1. Part type switching controlled by PLC

Time diagram of part type switching is as follows:

STROBE-TYPE

DATA-IN-7~0

OUT-TYPE

DATA-OUT-7~0

21 3 4 5 6

1) PLC: Set of Data-In-7..0 according to requested part type.Remark: At Data-In-7..0 = 0 a request of current part type occurs, refer to next point.

2) PLC: After 1 ms (in next PLC cycle) set of Strobe-Type.

3) Reaction of eddyvisor®: The signals Data-Out reflect the conditions of the signals

Data-In and Out-Type becomes „1“.If the signals Data-Out do not correspond to the signals Data-In, it is probably breakof cable.Remark: Change of conditions of Data-In are forwarded now to Data-Out.

4) PLC: Reset of signal Strobe-Type - the signal Data-In remains active. Theeddyvisor switches the part type, if needed.

Remark: With falling edge of Strobe-Type the eddyvisor saves the condition of

Data-In-7..0 and starts part type switching. If Data-In-7..0 = „0“ at that moment, thereis no part type switching.

5) Reaction of eddyvisor: After part type switching the signals Data-Out and then

Out-Type are set to „0“.If the requested part type has already been set, switching time is minimised.In case of unsuccessful part type switching only Out-Type is reset - the signals Data-Out remains active. Unsuccessful part type switching is possible when the requestedpart type is not available or switching of the mode of a station would be required.




6) PLC: Reset of signals Data-In-7..0.

7.2. Part type request controlled by PLC

Time diagram of part type request is as follows:

STROBE-TYPE

DATA-IN-7~0

OUT-TYPE

DATA-OUT-7~0

1 2 3 4

1) PLC: Set of Strobe-Type at Data-In-7..0 = 0.

2) Reaction of eddyvisor: Output of current part type with Data-Out-7..0 and set ofOut-Type. Is the part type not identically at all station, the signals Data-Out-7..0 areset to „0“.

3) PLC: Reset of signal Strobe-Type.

4) Reaction of eddyvisor: Reset of Data-Out-7..0 and Out-Type to „0“.

Request of part type may be used in order to reset the signals Data-Out-7..0.


que desea que aparezca aquí.ibg Doc: 0713431e, 29 May 2008


8. Technical data

Dimensions eddyvisor®S W 410 mm x H 308 mm x D 271 mm

eddyvisor®HMI W 410 mm x H 308 mm x D 96 mm

eddyvisor®MS W 410 mm x H 308 mm x D 175 mm

Weight 13 kg (6 kg of that is eddyvisor®HMI)

Electrical data:

Supply voltage 90 - 260 V / 47 - 63 Hz

Internal fuse T 2.0 A

Recommended connection 4.0 A

Power consumption 120 VA

Operating temperature range:

Desktop version: 0°C to 40°C

Switch panel version: 0°C to 45°C

Storage temperature range: -20°C to 60°C

Internal power supply:

for optional supply of all VCONI-boards

voltage 24 Vdc

max. current 2.5 A

with electronic overload fuse




9. Glossary

eddyvisor®Registered trade mark of ibg Prüfcomputer GmbH

eddyvisor®C Instrument for crack detection, „Crack Test“

eddyvisor®S Instrument for structure test, „Structure Test“

eddyvisor®SC Instrument for structure test and crack detection

eddyvisorDS

eddyvisorDC

eddyvisorDSC

D means Desktop versionAll combinations are available as desktop version, theycan anytime be divided to switch panel versions.

eddyvisor®HMI Part of instrument operating unit (PC), „Human-Machine-Interface“

eddyvisor®MS Part of instrument measuring unit, structure test, „Module

Structure Test“

eddyvisor®MC Part of instrument measuring unit, crack detection, „Module

Crack Test“

eddyvisor®MSC Part of instrument measuring unit, structure and crack test

OK-parts Test parts which are sorted as OK

NG- / NOK-parts Test parts which are sorted as bad / NG / NOK

PMFTPreventive Multi-Frequency Test (structure test)Preventive Multi-Filter Test (crack detection)

VCONI eddyVisor CONnector I/O,I/O-board 32 in- and 32 outputs 24 Vdc (PLC),for use in measuring unit either slot 3 or in slot 6 - 7

VCONC2VCONC4VCONCH2VCONCH4

eddyVisor CONnector Crack Test,crack detection probe connection board for 2 or 4 probesVCONCH have only one big probe connector for rotatingheads, for use in measuring unit in slot 1 - 4

VCONS2VCONS4VCONS6VCONS8

eddyVisor CONnector Structure Test,coil connection board for 2 / 4 / 6 / 8 coils,for use in measuring unit in slots 1 - 4




10. Appendix


29 May 2008, ibg Doc: 0713431e


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