Program part one Thursday 14th April, last day Morning session Chair: Arnold de Groot Headline: Wire Rope 08:30 Innovative fatigue test methods for the evaluation of wire ropes service life and performance under heavy duty offshore applications Ronen Ashkenazi 09:15 Non‐destructive testing of large diameter steel wire ropes with intros instruments Dmitry Slesarev 10:00 Coffee / CraneExpo 10:15 Case study on the application of rope installation, examination, maintenance and discard criteria for the offshore wind energy sector, Sara Fletcher 10:45 Non ‐ destructive magneto‐inductive rope testing, Olivier Gronau
Table of Contents, Thursday 14th April Wednesday 13th April Innovative fatigue test methods for the evaluation of wire ropes service life and performance under heavy duty offshore applications Ronen Ashkenazi Non‐destructive testing of large diameter steel wire ropes with intros instruments, Dmitry Slesarev Case study on the application of rope installation, examination, maintenance and discard criteria for the offshore wind energy sector, Sara Fletcher Non ‐ destructive magneto‐inductive rope testing, Olivier Gronau Keynote speaker by invitation : Mr. Roland Verreet, Lecture: About consultants, test machines and wire rope failures Innovations in training, risk mitigation through virtual simulation based on lessons learned from Us military & aviation industries, Troy “Korn” Kehoe Competence‐upgrading: inspection and service of cranes and davits, Ian McCurdie, Canceled Design and implementation of effective simulation‐based training curriculum for offshore lift crew training, Arnold Free Closing/adjourn Svein Anders Eriksson, Chairman of the organising committee.
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Speaker
Ronen Ashkenazi, M.R.E. Matron Rope & Wire Rope Engineering LTD, ISR Lecture: Innovative fatigue test methods for the evaluation of wire ropes service life and performance under heavy duty offshore applications
Background: He is the technical manager and owner of M.R.E Matron Rope & Wire Rope Engineering. He was conducting the Ph. D degree at the Department of Mechanical Engineering Technion – Israel Institute of Technology Technion City – Haifa: The Mechanical Behavior and Fatigue Life of Wire Ropes
Innovative Fatigue Test Methods for The Evaluation of Wire Ropes Service Life and Performance Under Heavy Duty Offshore Applications Dr . Ronen Ashkenazi M.R.E. Matron Rope & Wire Rope Engineering LTD
The 16th North Sea Offshore Crane and Lifting Conference 12th – 14th April 2011
M.R.E. MATRON Rope & Wire Rope Engineering LTD
Contents 1. The need of the end user: comparing between ropes: decision 2. Loading cycle definition 3. Reverse bending with fluctuating dynamic tension 4. Rope degradation process 5. Results and conclusions
M.R.E. MATRON Rope & Wire Rope Engineering LTD
The need for the testing and evaluating rope performance In specific high demand applications the rope performance and service life is a critical parameter and may have a considerable impact on operation, maintenance and production costs
M.R.E. MATRON Rope & Wire Rope Engineering LTD
The need of the end user: • Reliable rope:
A rope which will under fair machine and maintenance conditions will provide reasonable service life • Detectable predicted and understandable deterioration process with no surprises (internal breaks, strand contacts ) • Economical Reasonable costs • Repeatability product performance
M.R.E. MATRON Rope & Wire Rope Engineering LTD
The need of the end user: • To have a technical based decision with regard to the selection of the rope type and supplier. • To reduce risks and potential costs in new rope trials. • To follow on rope quality in supply • Characterize the specific rope deterioration process - Core deterioration: internal breaks - Strand contact breaks - Diameter reduction during service: abrasion + core radial contraction - Rope elongation - outer breaks
M.R.E. MATRON Rope & Wire Rope Engineering LTD
An example of a project: Comparison between ropes performance for specific heavy duty grab crane The application: A grab crane 45 ton : payload 30 ton 2 sets R & L 38 and 40 mm closing and hoisting ropes IWRC Drum: One layer D/d= 40, speed= 3 m’/sec Working 22 hours a day, 3 shifts Reasonable service life : 1.5 E 6 Ton 60,000 loading cycles M.R.E. MATRON Rope & Wire Rope Engineering LTD
M1
M2
M3
M.R.E. MATRON Rope & Wire Rope Engineering LTD
Loading cycle
F
Loading
13 Ton Un loading
Initial loading
4 Ton 0 Ton
זמן
M.R.E. MATRON Rope & Wire Rope Engineering LTD
Loading cycle of the closing ropes F
Assumption: during closing the closing rope will share: 65% of the load
Loading
Initial loading Grab closing
13 Ton
5 Ton
Un loading
Initiation of bending 4 Ton 0 Ton
t M.R.E. MATRON Rope & Wire Rope Engineering LTD
M.R.E. MATRON Rope & Wire Rope Engineering LTD
3 different segments
M.R.E. MATRON Rope & Wire Rope Engineering LTD
Loading cycle of the closing ropes Control parameters 1. Initial loading before travelling/bending: closing load 2. Speed 3. Acceleration, deceleration rate 4. Loading rate 5. Maximal load: 2% accuracy 6. Load after un- loading: empty grab weight 7. Delays at the end of trip Load control: load cell installed at the rope termination M.R.E. MATRON Rope & Wire Rope Engineering LTD
1
2
3
4
5
M.R.E. MATRON Rope & Wire Rope Engineering LTD
Test program includes
A
Core construction
B
C
Compacting level
Lubricant
Plastic layer Diameter 38 mm & 40 mm Initial diameter M.R.E. MATRON Rope & Wire Rope Engineering LTD
Confidentiality with regard to rope Supplier and construction
Test program includes: •Rope were not lubricated during the test: • Sheaves were re-grooved after each testing • Similar loading conditions : Stroke control , speed control , de/acceleration Load control
Measurements during testing : • Elongation during cycling • Broken wires: Visual and MRT • Diameter • Deterioration rate along the different rope segments
M.R.E. MATRON Rope & Wire Rope Engineering LTD
M.R.E. MATRON Rope & Wire Rope Engineering LTD
No. of broken wires over 6d and 30 d
14 12 10 8 6
Rope C
Rope A
Rope B
4 2
1
4
6
8
10
12
14
M.R.E. MATRON Rope & Wire Rope Engineering LTD
16
18
20
Cycles *1000
Results and conclusions 3 different ropes were tested under similar loading cycle and conditions
1. Different rope deterioration process and rates were observed 2.
Lubricants have a major impact on fatigue life
3. Core structure and plastic layer considerably influence service life 4. A correlation between rope deterioration and elongation was observed 4. Wire coating and compacting level have considerable impact on fatigue life of the individual wire: crack initiation process 5. Different elongation rate and levels were observed 6. Good agreement between laboratory tests and filed experience
M.R.E. MATRON Rope & Wire Rope Engineering LTD
• The testing under real application loading is necessary and
provides
reliable
results
with
regard
to
rope
performance under the specific application. • Test must includes all machine/rope interfaces and dynamics
M.R.E. is focusing on the design of testing rigs to simulate the real loading conditions: Deep mining (Koepe & Drum), mooring lines, heavy duty cranes, high rise elevators, aerospace & space applications
M.R.E. MATRON Rope & Wire Rope Engineering LTD
Testing at the wire level: Understanding rope mechanics under the specific loading Strain and stress measurements along individual wires during cyclic Rotation + TT loading
M.R.E. MATRON Rope & Wire Rope Engineering LTD
Speaker
Dmitry Slesarev, INTRON PLUS, RU Lecture: Non‐destructive testing of large diameter steel wire ropes with Intros instruments
Background: Dmitry Slesarev, PhD, R&D Director of “INTRON PLUS”, developed several diagnostic software systems, also system for wire rope deterioration assessment
Non-destructive testing of large diameter steel wire ropes with Intros instruments
Slesarev D., Vorontsov A. INTRON PLUS, Russia
Magnetic non-destructive testing of wire ropes • Reflected in industrial regulations and codes, for example: BS EN 12927-2004, ASTM 1571, IMCA SEL 023 IMCA M 197 • Large experience for more than 30 years • Conventional applications: mining industry, ropeways, cranes, cable-stayed structures
Application of magnetic rope testing in lifting facilities
Testing of hoist ropes in the paper mill
Off-shore applications
Oil & Gas platforms
Vessel cranes
Off-shore applications
Inspection of off-shore crane rope by Sakhalin
MFL principle of operation
Sensors measure magnetic flux leakage, caused by material discontinuity
LMA and LF charts
Rope chart of some heavy duty shaft rope
Distribution of LMA and LF of the shaft rope during 3 consecutive inspections
Calculation of Rope’s Safety Factor The calculation is based on: • Rope diameter and construction • Nominal rope load and loading conditions (tension with/without twisting, bending) • Distribution of LMA and LF over the length of the rope
Distribution of Safety Factor of the Shaft Rope during 3 Consecutive Inspections
Degradation of Safety Factor with a Time vs. Loading Cycles
Degradation of Relative Strength with a Time vs. Loading Cycles
Effect of Broken Wire Location on Residual Strength for Different Rope Constructions
Rotation-resistant multi-strand rope
Non rotation-resistant hoisting rope
Strength loss depending on failure location and operating condition Loss of Strength, %
Rope
Loss of Metallic Area, %
Tension
Tension with Rotation
Outer wires breaks
Core wires breaks
Outer wires breaks
Core wires breaks
DIEPA 1315 CZ 15x76x26/6x7+IWRC(1x25)
7.0
6.2
8.0
3. 2
10.6
PYTHON 8F7K N 8x25+IWRC(1x7+6x7)
7.3
6.3
10.8
7.9
22.1
Conclusion Actual safety factor depends considerably on failure location and operation condition of the rope.
Intros magnetic rope testing instruments MH 24-64 MH 6-24
MH 60-85
MH 20-40
MH 80-120 MH 100-150
Intros Instruments for Big Diameter Wire Ropes
Range of rope diameters, mm
60 – 85 80 – 120 100 – 150
Speed of rope under inspection, m/s
0.2 – 1.5
Precision of LMA measurement, %
2.0
Sensitivity limit to an outer broken wire, % (relative to cross-section area)
0.12
Thank you! www.intron-plus.com
Speaker
Sara Fletcher Bridon International Ltd Lecture: Case study on the application of rope installation, examination, maintenance and discard criteria for the offshore wind energy sector
Background: Attained Bachelor Degree in Mechanical Engineering in 1993, then joined Bridon during which time has led the Technical Sales function for floating production moorings and deepwater deployment ropes. Currently responsible for development of rope technology needs for deepwater offshore applications.
Practical Application of Examination, Maintenance & Discard of Wire Rope 16th North Sea Offshore Cranes and Lifting Conference Stavanger Forum 12th – 14th April 2011
Sara Fletcher – Technical Development Manager Mike Bramley – Service Manager
Bridon International
Agenda • • • • • •
Wire Rope Integrity Product Selection for Equipment optimisation Installation Examination Discard Practical considerations
What is Wire Rope Integrity? Methods to ensure: • Through life safety of wire rope. • Specification & Installation. • Inspection & Examination. • Post retirement review. • Feedback. • Transparency & clarity of records. Objective: • Confidence in equipment for reliable operations.
Rope Selection • Application: – – – – –
Simple single load case Multi‐reeved crane Single fall large capacity crane Traction winches Heave compensation
• Requirements: – – – – – – –
Load transfer Tension Fatigue Bending Bend Fatigue Rotation Flexibility Etc..
Specification requirements Rope properties: Rope classification / Construction Diameter Length Tolerances International standard specifications Installation: Packaging Equipment Tension Application: SWL Terminations Sheave dimensions & profiles Fleet angles Gripping forces Not a total list!
Installation • Correct installation of the rope will have a positive effect on wire rope performance • Poor installation of the rope will have a negative effect on the rope performance.
Grooved drum systems aid good spooling
Installation • Correct installation of the rope will have a positive effect on wire rope performance • Apply back tension to the rope during installation: – at least 2% of the Minimum Breaking Load – or up to 25% of working tension (as training load)
• Training of large diameter complex rope constructions: – deploy in deep water – Cycle to remove construction effects
• Training the rope to optimise rope performance • Reflect back to rope selection – Define dimensional tolerance – Understand compressibility: Axial and radial
Lifetime Integrity Methodology The following five methodologies can be applied to provide wire rope integrity assurance: • • • • •
automatic discard (replacement) after a set period, thorough examination and inspection; non‐destructive examination; destructive tensile testing; and a range of post‐retirement activities which will provide feed‐back into the integrity management system. From IMCA M 194 Guidance on Wire Rope Integrity Management for Vessels in the Offshore Industry
Integrity Methodology ‐ Discard The following five methodologies can be applied to provide wire rope integrity assurance: • • • • •
automatic discard (replacement) after a set period, thorough examination and inspection; non‐destructive examination; destructive tensile testing; and a range of post‐retirement activities which will provide feed‐back into the integrity management system. From IMCA M 194 Guidance on Wire Rope Integrity Management for Vessels in the Offshore Industry
Visual Inspection
Integrity Methodology ‐ Discard The following five methodologies can be applied to provide wire rope integrity assurance: • • • • •
automatic discard (replacement) after a set period, thorough examination and inspection; non‐destructive examination; destructive tensile testing; and a range of post‐retirement activities which will provide feed‐back into the integrity management system. From IMCA M 194 Guidance on Wire Rope Integrity Management for Vessels in the Offshore Industry
NDE
LMA trace, % 4.0 3.0 2.0 1.0 0.0 -1.0 -2.0 -3.0 -4.0 12
13
14
15
16
17
16
17
LF trace, mV 40.0 30.0 20.0 10.0 0.0 -10.0 -20.0 -30.0 -40.0 12
13
14
15
Integrity Methodology ‐ Discard The following five methodologies can be applied to provide wire rope integrity assurance: • • • • •
automatic discard (replacement) after a set period, thorough examination and inspection; non‐destructive examination; destructive tensile testing; and a range of post‐retirement activities which will provide feed‐back into the integrity management system. From IMCA M 194 Guidance on Wire Rope Integrity Management for Vessels in the Offshore Industry
Integrity Methodology ‐ Discard The following five methodologies can be applied to provide wire rope integrity assurance: • • • • •
automatic discard (replacement) after a set period, thorough examination and inspection; non‐destructive examination; destructive tensile testing; and a range of post‐retirement activities which will provide feed‐back into the integrity management system. From IMCA M 194 Guidance on Wire Rope Integrity Management for Vessels in the Offshore Industry
Integrity Methodology ‐ Discard The following five methodologies can be applied to provide wire rope integrity assurance: • • • • •
automatic discard (replacement) after a set period, thorough examination and inspection; non‐destructive examination; destructive tensile testing; and a range of post‐retirement activities which will provide feed‐back into the integrity management system. From IMCA M 194 Guidance on Wire Rope Integrity Management for Vessels in the Offshore Industry
Discard • International Standard ISO 4309 • Considers the application: – Bend fatigue driven – Surface contact damage
• Considers the rope construction • Training & Competence
Risk Management Rope integrity = Confidence in equipment for reliable operations. Risk = probability x impact • Single Broken Wire: – Probability = high – Impact = low
• Broken rope – Probability = low – Impact = high
• Multiple Broken Wires in a similar location: – – – –
Make probability of identification – high Repair / Replace Prevent Make probability of it becoming a failure = low
• Maintenance & competence = reduction in Risk
Summary • • • • •
Rope Integrity Management is Risk Management Increased Competence & Maintenance reduces risk. Use all the tools practically available. Feed back ! Objective to ensure confidence in rope & equipment for reliable, safe, economic operations. Thank you FletcherS@bridon.com BramleyM@bridon.com
Speaker
Olivier Gronau, Rope Testing Centre‐DMT GmbH & Co. KG, DE Lecture: Non – destructive magneto‐inductive rope testing
Background: Studies at the “Otto‐von‐Guericke‐University” in Magdeburg. Final degree in 1986 as a Dipl.‐Ing. for materials engineering and testing. Since 2000 a personal accredited expert for the German mining industry. Present position as the head of the accredited laboratory for non‐destructive and destructive testing ‐rope testing centre‐ in Bochum, Germany
Non-Destructive Magneto-Inductive Rope Testing Olivier Gronau & Michael Leesker DMT GmbH & Co. KG DMT-Prüflaboratorium für Zerstörungsfreie und Zerstörende Prüfung -Seilprüfstelle(DMT Testing Laboratory for Non-Destructive and Destructive Testing -Rope Testing Centre-) Breaking Load Reduction as a Function of the Damaged Outer Wires
Number of Damaged Outer Wires per Strand (within Transverse Microsection)
16
15 % LMA 12 % LMA 10 % LMA 8 % LMA
14
12
10
8
6
4
2
0 0
5
10
15
20
25
30
35
Breaking Load Reduction [%]
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 1
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40
Non-Destructive Magneto-Inductive Rope Testing Agenda
NDT Techniques for Rope Inspection
History of MRT-Systems
Data Collection and Graphical Representation
Interpretation of MRT Results
Examples of MRT within the Offshore Industry
Conclusion
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 2
www.dmt.de
NDT Techniques for Rope Inspection
Visual Testing + Haptic Testing • • • •
coating condition corrosion and wear broken or cracked outer wires mechanical distortions or damages
Magneto-Inductive Testing
Ultrasonic & Magnetic Particle Testing
• broken and/or cracked outer and inner wires (LF) • loss of metallic cross section area (LMA)
• wire breaks/cracks and corrosion at the outer layer of fully-locked ropes and parallel wire bundles
• damages of all wires within the critical area at the sockets of parallel wire bundles
• wear and cracks within the anchorages, such as bolts and latches
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 3
www.dmt.de
Non-Destructive Magneto-Inductive Rope Testing Agenda
NDT Techniques for Rope Inspection
History of MRT-Systems
Data Collection and Graphical Representation
Interpretation of MRT Results
Examples of MRT within the Offshore Industry
Conclusion
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 4
www.dmt.de
History of MRT-Systems The -Rope Test Centre- was founded in Bochum in 1903 as a part of the "Westfälische Berggewerkschaftskasse". Electromagnetic Testing since 1931
Test Set-Up: - 2 DC coils á 1600 windings - 1 measuring coil á 100 windings - Galvanometer with optics for the enlargement of the pointer deflection
Practical Application: - constant velocity of the rope - inspection time approx. 6 hours per rope
A. Otto: Elektromagnetisches Verfahren zur Prüfung von Drahtseilen; Glückauf 69 (1933), S. 471 - 475 April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 5
www.dmt.de
History of MRT-Systems
Replacement of DC coils by yoke coils
Use of a flying spot line recorder -
D. van der Velden und H. T. Vossen Ein Gerät zum Prüfen von Drahtseilen auf elektromagnetischem Wege Glückauf 92 (1956) S. 792 bis 794
Use of differential coils
Use of a distance counter
Velocity independent signal amplitude -
H. Grupe Entwicklung einer Einrichtung zur Prüfung von Förderseilen nach dem magnetinduktiven Verfahren Forschungsberichte des Landes Nordrhein-Westfalen Nr. 954, 1961
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 6
www.dmt.de
History of MRT-Systems ď Ž
Replacement of the yoke coils by permanent magnets (middle of the 60s)
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 7
www.dmt.de
History of MRT-Systems
Replacement of the yoke coils by permanent magnets (middle of the 60s)
Measuring of the loss of metallic cross section area (middle of the 80s)
Use of rare earth magnets (beginning of the 90s)
Visual rope diameter measuring for research purposes
Industry PC based data acquisition device (middle of the 90s) -
Digital signal records on PCMCIA memory card
Use of Hall effect sensors (end of the 90s)
For ropes of parallel strands a new rope testing instrument is developed in a joint venture with the EMPA* at the moment
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 8
www.dmt.de
Non-Destructive Magneto-Inductive Rope Testing Agenda
NDT Techniques for Rope Inspection
History of MRT-Systems
Data Collection and Graphical Representation
Interpretation of MRT Results
Examples of MRT within the Offshore Industry
Conclusion
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 9
www.dmt.de
Data Collection and Graphical Representation
ď Ž ď Ž
Quantitative determination of wire breaks Qualitative determination of corrosion and/or abrasion
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 10
www.dmt.de
Data Collection and Graphical Representation
Original trace of wire breaks
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 11
Software for determination of wire break density
www.dmt.de
Data Collection and Graphical Representation Wire Break Density of a 52 mm Rope (6x35 WV) 16 test date: 24.02.2005 test date: 25.05.2005
Max. Mire Break Density within the Reference Length of 1,56 m
14
test date: 08.08.2005
12
10
8
6
4
2
0 10
60
110
160
210
260
310
360
410
460
510
560
610
660
710
760
810
860
910
Rope Length above the Cage [m]
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 12
www.dmt.de
Data Collection and Graphical Representation
ď Ž ď Ž
Quantitative determination of corrosion and/or abrasion Qualitative determination of wire breaks, partly also quantitative at outer wire breaks
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 13
www.dmt.de
Data Collection and Graphical Representation
Original trace of heavy corrosion
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 14
Software for determination of LMA
www.dmt.de
Data Collection and Graphical Representation LMA-Test Results on a 3-Layer Flat Strand Rope 14
test date: 14.08.2004 12
test date: 06.02.2005 test date: 26.06.2005
LMA [%] .
10
8
6
4
2
0
0
200
400
600
800
1000
1200
Rope Length above the Eastern Skip [m]
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 15
www.dmt.de
Non-Destructive Magneto-Inductive Rope Testing Agenda
NDT Techniques for Rope Inspection
History of MRT-Systems
Data Collection and Graphical Representation
Interpretation of MRT Results
Examples of MRT within the Offshore Industry
Conclusion
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 16
www.dmt.de
Interpretation of MRT Results Discard criteria are defined in different standards (DIN 15020 / ISO 4309)
Number and nature of broken wires
Rate of increase of wire breaks
Localized grouping of wire breaks
…
…
Reduction of rope diameter
External and internal wear / corrosion
…
… April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 17
www.dmt.de
Interpretation of MRT Results 1,8
Coil-Sensor Hall-Sensor
1,6 1,4
LMA [%]
1,2 1 0,8 0,6 0,4 0,2 0 0
50
100
150
200
250
300
350
400
450
500
Gap between wire ends [mm]
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 18
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Interpretation of MRT Results Calibration Signals LF-Coil 1
LF-Coil 2
LF-Coil 1 + Coil 2
+ LMA
Coil-Sensor
Hall-Sensor
LMA trace, % 1,0 0,0 -1,0 -2,0 -3,0
-
-4,0 -5,0 13
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 19
14
15
16
17
www.dmt.de
Interpretation of MRT Results
centre
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 20
and acceleration area of a rope
www.dmt.de
Interpretation of MRT Results
Breaking Load Reduction as a Function of the Damaged Outer Wires
Number of Damaged Outer Wires per Strand (within Transverse Microsection)
16
15 % LMA 12 % LMA 10 % LMA 8 % LMA
14
12
10
8
6
4
2
0 0
5
10
15
20
25
30
35
40
Breaking Load Reduction [%]
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 21
www.dmt.de
Non-Destructive Magneto-Inductive Rope Testing Agenda
NDT Techniques for Rope Inspection
History of MRT-Systems
Data Collection and Graphical Representation
Interpretation of MRT Results
Examples of MRT within the Offshore Industry
Conclusion
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 22
www.dmt.de
Examples of MRT within the Offshore Industry During the production
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 23
www.dmt.de
Examples of MRT within the Offshore Industry During the installation on site
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 24
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Examples of MRT within the Offshore Industry During the service inspection
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 25
www.dmt.de
Non-Destructive Magneto-Inductive Rope Testing Agenda
NDT Techniques for Rope Inspection
History of MRT-Systems
Data Collection and Graphical Representation
Interpretation of MRT Results
Examples of MRT within the Offshore Industry
Conclusion
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 26
www.dmt.de
Conclusion
MRT is an additional tool for rope testing
Inner damages can be determined quantitatively
MRT + VT are necessary for the determination of the deterioration
Information about service time and periodic MRT are required for a lifetime assessment
April 14th 2011 | The 16th NSOCLC in Stavanger 2011 | Slide 27
www.dmt.de
We Look Forward to Your Questions! Your Contact Person: Olivier Gronau Mining Service / -Rope Testing CentreDMT GmbH & Co. KG Dinnendahlstrasse 9 D-44809 Bochum, Germany Phone +49 234 957 157-52 Fax +49 234 957 157-50 Mobile +49 170 5657 663 Olivier.Gronau@dmt.de
Member of TÜV NORD Group April 2010 | Vorlagen Präsentationsfolien | Folie 28
www.dmt.de
Program part two Thursday 14th April, last day Wire Rope continuous Chair: Chair: Arnold de Groot 11:15 – 12:15 NB see time change Keynote speaker by invitation : Mr. Roland Verreet Lecture: About consultants, test machines and wire rope failures 12:15‐ 13:00 Lunch
Speaker
Roland Verreet, Wire rope Technology Aachen Lecture: About consultants, test machines and wire rope failures
Background: Diploma engineer University of Aachen, Germany. Working in the wire rope industry since 36 years and 26 years as a self‐employed consultant
Program part three Thursday 14th April, last day Afternoon session Chair: Kevin Murdoch Headline: Human Factors and Training 13:00 Innovations in training, risk mitigation through virtual simulation based on lessons learned from Us military & aviation industries, Troy “Korn” Kehoe 13:45 Competence‐upgrading: inspection and service of cranes and davits, Ian McCurdie 14:15 Design and implementation of effective simulation‐based training curriculum for offshore lift crew training, Arnold Free 15:00 Closing/adjourn Svein Anders Eriksson, Chairman of the organising committee. 15:30 Bus to the airport
Speaker
Troy Kehoe, Check 6, US Lecture: Innovations in training, risk mitigation through virtual simulation based on lessons learned from US military & aviation industries
Background: He is an engineering graduate of the University of Southern California with an advanced degree in Aviation Safety. He has proudly served in the United States Marine Corps as a combat AV‐8B Harrier pilot, flew internationally for American Airlines, and served on the pilot training team for Lockheed Martin’s Joint Strike Fighter Program.
Innovations in Training
“Try not to have a good time…this is supposed to be educational” Charles Schulz
The Check 6 Culture Next Generation Training Challenges F22 Lessons Learned Instructional Systems Design Gaming Evolution Human “Innovations” ◦ ◦ ◦ ◦
Human Factors CRM Checklist Discipline Leadership
“Check 6” is a term fighter pilots use to describe checking your wingman’s most vulnerable location, where they cannot see… behind their aircraft…their six o'clock. A culture defined by: Leadership Teamwork Performance Safety Training
The same techniques that allow humans to master this environment….…
…… Definitively allow the mastering of your environment.
• • • • • • •
Combat Seasoned Fighter Pilots TOPGUN Trained Special Forces Operative Training Systems Development Experts Diverse Corporate Experience Oil Patch Experience Dynamic Speakers
Troy “Korn” Kehoe • AV‐8B Harrier Pilot
• Aviation Safety Officer • MAWTS Graduate • F‐35 Training Systems & Simulator Test Pilot • American Airlines Pilot • University of Southern California
Chico, TX
• • • • • • • • • •
Technological Advances Crew Turnover Rate Throughput Requirements Defining Proficiency Decay Analysis (Currency) Emergency Procedures Initial Training vs. Continuation Training Human Factors Diverse Educational Demographic Multi‐Cultural Training
Conditions Training Task List
Standards of Performance
What media will achieve LO?
Media Analysis
Decay Analysis
Currency
Do we need Simulation?
Initial Training
Level of Fidelity
Proficiency Metrics
Recurrent Training
Continuation Training
Immersive Environments are important! ◦ Conditions and Standards define Simulation Requirements
“Imagination is more important than Higher Frequency Training = Portable knowledge.” ◦ Remote Training at the work site Rehearse critical jobs Albert Einstein Review Response to Emergencies in Immersive Environment
Team Training is Essential Look to Gaming
(9X)
Lucky
Perfect Precise Efficient Effective Safe Hazard
Violation Incident Accident Fatality
Precision Operations are Inherently Safe!
Situational Awareness Assertiveness Decisiveness Communication Leadership Adaptability / Flexibility Mission Analysis
Technology Solution
◦ Training cannot be an afterthought ◦ “Entertrainment” – Next Generation Learning Environment ◦ Training frequency should be measured in days – Not Years!
Human Solution ◦ ◦ ◦ ◦
Phenomenal Leadership at all levels Arm yourself with knowledge Adopt a Checklist Discipline Culture Stop targeting safety as the goal!
Canceled Ian McCurdie, Hytek A/S, UK Lecture: Competence‐upgrading: Inspection and service of cranes and davits
Speaker
Arnold Free, CMLabs / Vortex, Montreal, CA Lecture: Design and implementation of effective simulation‐based training curriculum for offshore lift crew training Background: He has earned his Ph.D. in Engineering from Cambridge University, UK and draws on nearly 30 years of engineering and software experience in simulation, training and operations planning. He has helped organizations navigate how they use simulation technology to improve safety and better business practices
The work is simulated. The skills are real.
If you believe training is expensive. Try ignorance!
An evidence-based approach to simulation-driven lift planning and learning. A brief look at how simulation can transform processes in the offshore lift industry.
How do we create effective learning organizations? Look at the empirical evidence.
Myth. People learn through different training styles.
Evidence. There is no evidence that we learn through different styles (auditory, visual, etc). There is strong evidence we learn by doing.
Myth. We learn best through formal/structured programs.
Evidence. There is no evidence that we best learn through formal training methods. There is strong evidence that skills retention is better with informal and repetitive learning.
Myth. Information = knowledge.
Evidence. Learning methods that provide information through presentations (with instructor or via elearning) are less effective – telling is not learning. There is strong evidence that learning effectiveness is much higher when the student is actively engaged in problem solving.
Myth. Practice makes perfect.
Evidence. Practice is important when learning skills, but practice alone is not what really matters and practicing incorrect behaviour can have a very negative impact. What makes the difference to effective learning is planning, doing and corrective feedback.
Simulation can help the Learning Organization Delivering consistent training based on proven methods. Involving complete processes, operations and teams. Fostering inquiry, dialogue and review. Building continuous awareness of, and interaction with the environment through repetition.
About Vortex Training Solutions Vortex creates engaging virtual environments to enhance preparedness, performance and mission outcome for critical equipment operations.
Vortex - simulation leadership in Europe PNI Training - Norway
BAE Systems - UK
Lego - Denmark
Babcock - UK
Subsea7 - UK
John Deere - Finland
Examples. Simulation assists in many areas Engineering – understanding machine performance, operations behaviour, ergonomics Operations planning – lift planning, equipment coordination, access study Mission preparation – process documentation, mission rehearsal, mission briefing Training – skills development, certification and testing, crew resource management
To be effective Require common tools and processes that support the sharing of assets – engineering builds a simulation that can be loaded into a simulator for training Scalable technology – from web to desktop to immersive Fidelity is critical – risk of negative training, poor prediction of outcomes
Use Case: Lift planning Experimentation, understanding the environment, planning safe lifts, communicating procedures
Use Case: Equipment systems awareness Machine systems are complex, many configurations, understanding hydraulic and electrical systems
Use Case: Lift crew team-training Built around OMHEC training guidelines. Teamwork can not be taught in a classroom Job planning and toolbox talk Full mission, team‐based training solutions for the operator, signalman and rigger Tandem lifts with two cranes Integrated inspection training After action team review
Use Case: Project life-cycle training Continuous training through‐out the life of the project Testing lift plans in advance
Use Case: Augmented reality Combine the real and the virtual for task support
Use Case: Integrated task training Crane configuration and load management system training
Use Case: Inspection and situational awareness Machine or site walk around, load and lifting gear inspection
Is simulation-based training effective? The evidence is very clear Recent study in several industries – simulation‐based training was found to be effective and recommended for on‐going or expanded use in all cases Recent Vortex survey of operators and instructors (about 300 individuals surveyed) who had used simulators 87% of instructors stated that simulation based training was very effective at skills development 75% of operators stated they would find it extremely useful to practice in a simulator before performing a lift or learning new procedures
Essential Elements of Effectiveness Delivering consistent training throughout project teams and lifecycle – engineering, planning, operations. Involving complete processes, operations and teams. Fostering inquiry, dialogue and review. Building continuous awareness of, and interaction with the environment through repetition.
Thanks.
The work is simulated. The skills are real.
Speaker
Svein Anders Eriksson, Discipline leader, Petroleum Safety Authority, NO
Closing/ ajourn The 16th North Sea
Offshore Cranes and Lifting Conference 12th – 14th April 2011
Svein Anders Eriksson Discipline leader Logistics and Emergency Preparedness, PSA Norway
svein.eriksson@ptil.no www.ptil.no
PTIL/PSA
What have we covered during the conference? • • • • • •
Regulatory focus areas Improvements and new technology Heavy lifting Maintenance and inspection Wire ropes Human factors and training
PTIL/PSA
Have we managed to….. • Share best practice and experience with colleagues in the industry? • Create new relations and renew old? • Provide for increased safety awareness?
• Here are my hopes:
PTIL/PSA
Today’s and tomorrow’s challenge We will not see colleagues being crushed between containers
4
28/04/2011 PTIL/PSA
Today’s and tomorrow’s challenge We will not see people being snatched by tag lines
5
28/04/2011 PTIL/PSA
Today’s and tomorrow’s challenge We will not see boom failures or technical breakdowns, which can seriously hurt people and do damage to property
6
28/04/2011 PTIL/PSA
Today’s and tomorrow’s challenge We will not see people getting squeezed between containers during lifting operations
PTIL/PSA
Today’s and tomorrow’s challenge We will not see damage to personnel an property due to use of unsafe drilling hoisting tools
PTIL/PSA
If you want to improve safety in safety critical operations ‌..
PTIL/PSA
Welcome to the next offshore cranes and lifting conference Venue and dates:
• Aberdeen • 24th – 26th April 2012
PTIL/PSA