Advanced Numerical and Analytical Methods for Assessing Concrete Sewers and Their Remaining Service Life
Pipelines are extensively used engineering structures
which convey fluid from one place to another. Most of the time,
pipelines are placed underground and are encumbered by soil weight
and traffic loads. Corrosion of pipe material is the most common
form of pipeline deterioration and should be considered in both the
strength and serviceability analysis of pipes.
The study in this research focuses on concrete pipes in sewage
systems (concrete sewers). This research firstly investigates how to
involve the effect of corrosion as a time dependent process of
deterioration in the structural and failure analysis of this type of pipe.
Then three probabilistic time dependent reliability analysis methods
including the first passage probability theory, the gamma distributed
degradation model and the Monte Carlo simulation technique are
discussed and developed. Sensitivity analysis indexes which can be
used to identify the most important parameters that affect pipe failure
are also discussed.
The reliability analysis methods developed in this paper contribute
as rational tools for decision makers with regard to the strengthening
and rehabilitation of existing pipelines. The results can be used to
obtain a cost-effective strategy for the management of the sewer
system.
[1] ASCE Manuals and Reports of Engineering Practice No. 60, Gravity
Sanitary Sewers, 2nd edition, American Society of Civil Engineers, New
York, USA, 2007
[2] American Concrete Pipe Association, ACPA, Concrete pipe – design
manual, Library of Congress catalog number 78-58624, 2007
[3] Moser, A. P. and Folkman, S., Buried piep design, Thgird edition, Mc
Graw Hill, 2008
[4] Ahammed, M. and Melchers, R. E. , Probabilistic analysis of
underground pipelines subject to combined stress and corrosion,
Engineering Structures, 1997, 19(12), 988-994.
[5] Sharma, K. J., Yuan, Z., de Haas, D., Hamilton G., Corrie, S. and Keller,
J., Dynamics and dynamic modelling of H2S production in sewer
systems, Water Research, 2008, 42, 2527 – 2538
[6] Pomeroy, R.D., The problem of hydrogen sulphide in sewers. Clay Pipe
Development Association, 1976
[7] ASCE Manuals and Reports of Engineering Practice - No. 69., Sulphide
in Wastewater Collection and Treatment Systems, American Society of
Civil Engineers, 1989
[8] Zhang, L., P. De Schryver, B. De. Gusseme, W. De Muynck, N. Boon
and W. Verstraete , Chemical and biological technologies for hydrogen
sulphide emission control in sewer systems: A review. Water Research,
2008, 42(1-2), 1-12.
[9] OFWAT., (2002), ‘Maintaining Water and Sewerage Systems in
England and Wales, Our Proposed Approach for the 2004 Periodic
Review’, London
[10] The Urban Waste Water Treatment Directive, 91/271/EEC, Waste water
treatment in the United Kingdom – 2012 Implementation of the
European Union Urban Waste Water Treatment Directive –
91/271/EEC, Department for Environment, Food and Rural Affairs, UK
[11] Vincke, E., Biogenic sulfuric acid corrosion of concrete: microbial
interaction, simulation and prevention. Ph.D. Thesis, Faculty of Bioengineering
Science, University Ghent, Ghent, Belgium, 2002, pp. 7–9.
[12] Grigg, N. S., Infrastructure management systems, Water, wastewater,
and stormwater infrastructure management, Lewis Publishers, Boca
Raton, FL, 2003, 1–17
[13] Salman, B. and Salem, O., (),Modeling Failure of Wastewater Collection
Lines Using Various Section-Level Regression Models, ASCE Journal
of Infrastructure Systems, 2012, Vol. 18, No. 2, June 1
[14] ASTM E632-82(1996) Standard Practice for Developing Accelerated
Tests to Aid Prediction of the Service Life of Building Components and
Materials
[15] De Belie, N., Monteny, J., Beeldens, J. A., Vincke, E.,VanGemert, D.
and Verstraete, W., Experimental research and prediction of the effect of
chemical and biogenic sulfuric acid on different types of commercially
produced concrete sewer pipes, journal of Cement and Concrete
Research, 2004, 34, 2223–2236
[16] Davis, P., De Silva, D., Gould, S. and Burn, S., Condition assessment
and failure prediction for asbestos cement sewer mains, Pipes
WaggaWagga Conference, Charles Sturt University, WaggaWagga,
New South Wales, Australia, 2005
[17] Davis, P., De Silva, D., Marlow, D., Moglia, M., Gould, S. and Burn, S.,
Failure prediction and optimal scheduling of replacements in asbestos
cement water pipes, Journal of Water Supply: Research and
Technology— AQUA, 2008, 57.4
[18] Mahmoodian, M. and Alani, A., Multi failure mode assessment of buried
concrete pipes subjected to time dependent deterioration using system
reliability analysis, Journal of failure analysis and prevention: 2013,
Volume 13, Issue 5, Page 634-642
[19] Mahmoodian, M. and Alani, A., Time dependent reliability analysis of
underground concrete pipes subjected to sulphide corrosion, 11th
International Conference on Structural Safety & Reliability, 2013, 16-20
June, New York, USA
[20] Mahmoodian, M. and Alani, A., Modelling deterioration in concrete
pipes as a stochastic Gamma process for time dependent reliability
analysis, ASCE, Journal of pipeline systems engineering and practice,
2014, Volume 5, Issue 1, 04013008
[21] Alani, A., Faramarzi, A., Mahmoodian, M. and Tee K. F., Prediction of
sulphide build-up in filled sewer pipes, Journal of Environmental
Technology, 2014, http://dx.doi.org/10.1080/09593330.2014.881403,
[22] Cheung M.S. & Kyle B.R., Service life prediction of concrete structures
by reliability analysis. Journal of construction and building materials,
1996, 10(1) 45-55
[23] Freudenthal, A. M., Safety and the probability of structural failure,
Transactions, 121, 1337-1397 ASCE, 1956
[24] Melchers, R E, Structural Reliability Analysis and Prediction, 2nd
Edition, John Wiley and Sons, Chichester, 1999.
[25] Li, C.Q., Time dependent reliability analysis of the serviceability of
corrosion affected concrete structures. International Journal of Materials
& Structural Reliability, 2005, Vol.3, (2) 105-116
[26] Li, C. Q., and Mahmoodian, M., Risk Based Service Life Prediction of
Underground Cast Iron Pipes Subjected to Corrosion, Journal of
Reliability Engineering & System Safety, Volume 119, November
2013,, Pages 102–108
[27] van Noortwijk, J.M. and Pandey M.D., A stochastic deterioration
process for time-dependent reliability analysis, Proceedings of the
Eleventh IFIP WG 7.5 Working Conference on Reliability and
Optimization of Structural Systems, 2-5 November 2003, Banff, Canada,
pages 259-265
[28] Mahmoodian, M. and Alani, A., , A gamma distributed degradation rate
(GDDR) model for time dependent structural reliability analysis of
concrete pipes subject to sulphide corrosion, International Journal of
Reliability and Safety (in press), 2014
[29] Mann, E. and Frey, J., Optimized pipe renewal programs ensure costeffective
Asset management, Pipelines 2011: pp. 44-54
[30] Dawotola, A.W., Trafalis, T.B., Mustaffa, Z.,. vanGelder, P.H.A.J.M,
Vrijling, J.K., (2012), Risk based maintenance of a cros-country
petroleum pipeline system, Journal of Pipeline Systems Engineering and
Practice. Submitted September 2, 2011; accepted July 13, 2012
[31] Bogdanoff, J.L. and Kozin, F., Probabilistic Models of Cumulative
Damage, John Wiley & Sons: New York, 1985
[32] Nicolai, R.P., Budai, G., Dekker, R. and Vreijling, M., Modeling the
deterioration of the coating on steel structures: a comparison of methods.
In proceedings of the IEEE Conference on Systems, Man and
Cybernetics, IEEE, Danvers, 2004, pp. 4177-4182.
[33] Noortwijk, J.M. and Frangopol, D.M., Two probabilistic life-cycle
maintenance models for deteriorating civil infrastructures. Probabilistic
Engineering Mechanics, 2004, 19(4), 345 – 359. p. 77–83.
[34] Papoulis, A. and Pillai S.U., , Probability, random variables, and
stochastic processes. Fourth edition, McGraw-Hill, New York, 2002,
852p
[35] Camarinopoulos, L., Chatzoulis, A., Frontistou-Yannas, S. and
Kallidromitis, V., Assessment of the time-dependent structural reliability
of buried water mains, Reliability Engineering and System Safety, 1999,
65, 41-53.
[36] Sadiq, R., Rajani, B. and Kleiner, Y., Probabilistic risk analysis of
corrosion associated failures in cast iron water mains, Reliability
Engineering & System Safety, 2004, 86(1), 1-10.
[37] Yamini, H. and B. J. Lence, Probability of Failure Analysis due to
Internal Corrosion in Cast-Iron Pipes, Journal of Infrastructure Systems,
Vol. 16, No. 1, 2009
[38] Val, D. V. and Chernin, L., Serviceability Reliability of Reinforced
Concrete Beams with Corroded Reinforcement, Journal of Structural
Engineering, Vol. 135, No. 8, August 1, 2009
[39] Ditlevsen, O., and Madsen, H. O., Structural Reliability Methods, John
Wiley and Sons, 1996
[40] Rubinstein, R. Y. and Kroese, D. P., Simulation and the Monte Carlo
Method, second edition, John Wiley and Sons, 2008
[41] Kong J. S., and Frangopol D. M., Sensitivity Analysis in Reliability-
Based Lifetime Performance Prediction Using Simulation, Journal of
Materials in Civil Engineering, Vol. 17, No. 3, June 1, 2005
[42] Saltelli, A., Tarantola, S., Campolongo, F., and Ratto, M., Sensitivity
analysis in practice: A guide to assessing scientific models, Wiley, New
York, 2004
[43] Alani, A. and Mahmoodian, M., Sensitivity analysis for reliability
assessment of concrete pipes subjected to sulphide corrosion, accepted
for publication, Journal of Urban Water, 2014
[44] Ahammed, M. & Melchers, R.E., ‘Reliability of underground pipelines
subject to corrosion’, Journal of Transportation Engineering, Vol. 120,
No. 6, Nov/Dec 1994
[45] EPA 540-R-02-002, Risk Assessment Guidance for Superfund: Volume
III - Part A, Process for Conducting Probabilistic Risk Assessment,
Office of Emergency and Remedial Response U.S. Environmental
Protection Agency Washington, DC 20460, 2001
[1] ASCE Manuals and Reports of Engineering Practice No. 60, Gravity
Sanitary Sewers, 2nd edition, American Society of Civil Engineers, New
York, USA, 2007
[2] American Concrete Pipe Association, ACPA, Concrete pipe – design
manual, Library of Congress catalog number 78-58624, 2007
[3] Moser, A. P. and Folkman, S., Buried piep design, Thgird edition, Mc
Graw Hill, 2008
[4] Ahammed, M. and Melchers, R. E. , Probabilistic analysis of
underground pipelines subject to combined stress and corrosion,
Engineering Structures, 1997, 19(12), 988-994.
[5] Sharma, K. J., Yuan, Z., de Haas, D., Hamilton G., Corrie, S. and Keller,
J., Dynamics and dynamic modelling of H2S production in sewer
systems, Water Research, 2008, 42, 2527 – 2538
[6] Pomeroy, R.D., The problem of hydrogen sulphide in sewers. Clay Pipe
Development Association, 1976
[7] ASCE Manuals and Reports of Engineering Practice - No. 69., Sulphide
in Wastewater Collection and Treatment Systems, American Society of
Civil Engineers, 1989
[8] Zhang, L., P. De Schryver, B. De. Gusseme, W. De Muynck, N. Boon
and W. Verstraete , Chemical and biological technologies for hydrogen
sulphide emission control in sewer systems: A review. Water Research,
2008, 42(1-2), 1-12.
[9] OFWAT., (2002), ‘Maintaining Water and Sewerage Systems in
England and Wales, Our Proposed Approach for the 2004 Periodic
Review’, London
[10] The Urban Waste Water Treatment Directive, 91/271/EEC, Waste water
treatment in the United Kingdom – 2012 Implementation of the
European Union Urban Waste Water Treatment Directive –
91/271/EEC, Department for Environment, Food and Rural Affairs, UK
[11] Vincke, E., Biogenic sulfuric acid corrosion of concrete: microbial
interaction, simulation and prevention. Ph.D. Thesis, Faculty of Bioengineering
Science, University Ghent, Ghent, Belgium, 2002, pp. 7–9.
[12] Grigg, N. S., Infrastructure management systems, Water, wastewater,
and stormwater infrastructure management, Lewis Publishers, Boca
Raton, FL, 2003, 1–17
[13] Salman, B. and Salem, O., (),Modeling Failure of Wastewater Collection
Lines Using Various Section-Level Regression Models, ASCE Journal
of Infrastructure Systems, 2012, Vol. 18, No. 2, June 1
[14] ASTM E632-82(1996) Standard Practice for Developing Accelerated
Tests to Aid Prediction of the Service Life of Building Components and
Materials
[15] De Belie, N., Monteny, J., Beeldens, J. A., Vincke, E.,VanGemert, D.
and Verstraete, W., Experimental research and prediction of the effect of
chemical and biogenic sulfuric acid on different types of commercially
produced concrete sewer pipes, journal of Cement and Concrete
Research, 2004, 34, 2223–2236
[16] Davis, P., De Silva, D., Gould, S. and Burn, S., Condition assessment
and failure prediction for asbestos cement sewer mains, Pipes
WaggaWagga Conference, Charles Sturt University, WaggaWagga,
New South Wales, Australia, 2005
[17] Davis, P., De Silva, D., Marlow, D., Moglia, M., Gould, S. and Burn, S.,
Failure prediction and optimal scheduling of replacements in asbestos
cement water pipes, Journal of Water Supply: Research and
Technology— AQUA, 2008, 57.4
[18] Mahmoodian, M. and Alani, A., Multi failure mode assessment of buried
concrete pipes subjected to time dependent deterioration using system
reliability analysis, Journal of failure analysis and prevention: 2013,
Volume 13, Issue 5, Page 634-642
[19] Mahmoodian, M. and Alani, A., Time dependent reliability analysis of
underground concrete pipes subjected to sulphide corrosion, 11th
International Conference on Structural Safety & Reliability, 2013, 16-20
June, New York, USA
[20] Mahmoodian, M. and Alani, A., Modelling deterioration in concrete
pipes as a stochastic Gamma process for time dependent reliability
analysis, ASCE, Journal of pipeline systems engineering and practice,
2014, Volume 5, Issue 1, 04013008
[21] Alani, A., Faramarzi, A., Mahmoodian, M. and Tee K. F., Prediction of
sulphide build-up in filled sewer pipes, Journal of Environmental
Technology, 2014, http://dx.doi.org/10.1080/09593330.2014.881403,
[22] Cheung M.S. & Kyle B.R., Service life prediction of concrete structures
by reliability analysis. Journal of construction and building materials,
1996, 10(1) 45-55
[23] Freudenthal, A. M., Safety and the probability of structural failure,
Transactions, 121, 1337-1397 ASCE, 1956
[24] Melchers, R E, Structural Reliability Analysis and Prediction, 2nd
Edition, John Wiley and Sons, Chichester, 1999.
[25] Li, C.Q., Time dependent reliability analysis of the serviceability of
corrosion affected concrete structures. International Journal of Materials
& Structural Reliability, 2005, Vol.3, (2) 105-116
[26] Li, C. Q., and Mahmoodian, M., Risk Based Service Life Prediction of
Underground Cast Iron Pipes Subjected to Corrosion, Journal of
Reliability Engineering & System Safety, Volume 119, November
2013,, Pages 102–108
[27] van Noortwijk, J.M. and Pandey M.D., A stochastic deterioration
process for time-dependent reliability analysis, Proceedings of the
Eleventh IFIP WG 7.5 Working Conference on Reliability and
Optimization of Structural Systems, 2-5 November 2003, Banff, Canada,
pages 259-265
[28] Mahmoodian, M. and Alani, A., , A gamma distributed degradation rate
(GDDR) model for time dependent structural reliability analysis of
concrete pipes subject to sulphide corrosion, International Journal of
Reliability and Safety (in press), 2014
[29] Mann, E. and Frey, J., Optimized pipe renewal programs ensure costeffective
Asset management, Pipelines 2011: pp. 44-54
[30] Dawotola, A.W., Trafalis, T.B., Mustaffa, Z.,. vanGelder, P.H.A.J.M,
Vrijling, J.K., (2012), Risk based maintenance of a cros-country
petroleum pipeline system, Journal of Pipeline Systems Engineering and
Practice. Submitted September 2, 2011; accepted July 13, 2012
[31] Bogdanoff, J.L. and Kozin, F., Probabilistic Models of Cumulative
Damage, John Wiley & Sons: New York, 1985
[32] Nicolai, R.P., Budai, G., Dekker, R. and Vreijling, M., Modeling the
deterioration of the coating on steel structures: a comparison of methods.
In proceedings of the IEEE Conference on Systems, Man and
Cybernetics, IEEE, Danvers, 2004, pp. 4177-4182.
[33] Noortwijk, J.M. and Frangopol, D.M., Two probabilistic life-cycle
maintenance models for deteriorating civil infrastructures. Probabilistic
Engineering Mechanics, 2004, 19(4), 345 – 359. p. 77–83.
[34] Papoulis, A. and Pillai S.U., , Probability, random variables, and
stochastic processes. Fourth edition, McGraw-Hill, New York, 2002,
852p
[35] Camarinopoulos, L., Chatzoulis, A., Frontistou-Yannas, S. and
Kallidromitis, V., Assessment of the time-dependent structural reliability
of buried water mains, Reliability Engineering and System Safety, 1999,
65, 41-53.
[36] Sadiq, R., Rajani, B. and Kleiner, Y., Probabilistic risk analysis of
corrosion associated failures in cast iron water mains, Reliability
Engineering & System Safety, 2004, 86(1), 1-10.
[37] Yamini, H. and B. J. Lence, Probability of Failure Analysis due to
Internal Corrosion in Cast-Iron Pipes, Journal of Infrastructure Systems,
Vol. 16, No. 1, 2009
[38] Val, D. V. and Chernin, L., Serviceability Reliability of Reinforced
Concrete Beams with Corroded Reinforcement, Journal of Structural
Engineering, Vol. 135, No. 8, August 1, 2009
[39] Ditlevsen, O., and Madsen, H. O., Structural Reliability Methods, John
Wiley and Sons, 1996
[40] Rubinstein, R. Y. and Kroese, D. P., Simulation and the Monte Carlo
Method, second edition, John Wiley and Sons, 2008
[41] Kong J. S., and Frangopol D. M., Sensitivity Analysis in Reliability-
Based Lifetime Performance Prediction Using Simulation, Journal of
Materials in Civil Engineering, Vol. 17, No. 3, June 1, 2005
[42] Saltelli, A., Tarantola, S., Campolongo, F., and Ratto, M., Sensitivity
analysis in practice: A guide to assessing scientific models, Wiley, New
York, 2004
[43] Alani, A. and Mahmoodian, M., Sensitivity analysis for reliability
assessment of concrete pipes subjected to sulphide corrosion, accepted
for publication, Journal of Urban Water, 2014
[44] Ahammed, M. & Melchers, R.E., ‘Reliability of underground pipelines
subject to corrosion’, Journal of Transportation Engineering, Vol. 120,
No. 6, Nov/Dec 1994
[45] EPA 540-R-02-002, Risk Assessment Guidance for Superfund: Volume
III - Part A, Process for Conducting Probabilistic Risk Assessment,
Office of Emergency and Remedial Response U.S. Environmental
Protection Agency Washington, DC 20460, 2001
@article{"International Journal of Architectural, Civil and Construction Sciences:72041", author = "Amir Alani and Mojtaba Mahmoodian and Anna Romanova and Asaad Faramarzi", title = "Advanced Numerical and Analytical Methods for Assessing Concrete Sewers and Their Remaining Service Life", abstract = "Pipelines are extensively used engineering structures
which convey fluid from one place to another. Most of the time,
pipelines are placed underground and are encumbered by soil weight
and traffic loads. Corrosion of pipe material is the most common
form of pipeline deterioration and should be considered in both the
strength and serviceability analysis of pipes.
The study in this research focuses on concrete pipes in sewage
systems (concrete sewers). This research firstly investigates how to
involve the effect of corrosion as a time dependent process of
deterioration in the structural and failure analysis of this type of pipe.
Then three probabilistic time dependent reliability analysis methods
including the first passage probability theory, the gamma distributed
degradation model and the Monte Carlo simulation technique are
discussed and developed. Sensitivity analysis indexes which can be
used to identify the most important parameters that affect pipe failure
are also discussed.
The reliability analysis methods developed in this paper contribute
as rational tools for decision makers with regard to the strengthening
and rehabilitation of existing pipelines. The results can be used to
obtain a cost-effective strategy for the management of the sewer
system.", keywords = "Reliability analysis, service life prediction, Monte
Carlo simulation method, first passage probability theory, gamma
distributed degradation model.", volume = "8", number = "7", pages = "845-7", }
