Journal of Recent Activities in Infrastructure Science

This paper provides a comprehensive overview of existing state of underground pipelines in developed countries like the United States (US) and focus on history, performance, and barriers to long-term planning. Most of the pipeline infrastructure construction in the United States was done in 1950’s and 1960’s due to population and economic growth (Najafi, 2005). The Pipelines built during this period were by using cast iron and steel material.  The Pipes that are buried during this period are more than 70 years old, which needs to be replaced / renewed. According to ASCE 2017 Infrastructure report card, water and the wastewater pipelines received a grade D and D+ respectively, which states that there is a significant need in improving these infrastructure conditions. The main objective of this paper is to provide an overview of underground pipeline infrastructure in the developed countries with focus on the US. To study pipelines construction or renewal which is been done by traditional open-cut method or latest Trenchless technology. The scope of this paper is limited to water, wastewater and liquid and gas transmission pipeline infrastructure of underground utilities in the United States. The methodology of this paper discusses about the infrastructure needed for the operation and maintenance of pipeline infrastructure, the construction and renewal of the pipelines using traditional open-cut and Trenchless technology methods, the risks associated in constructing, renewing and operating the pipelines. It can be concluded, that the present scenario of water, wastewater, liquid and gas transmission pipelines are not meeting the required standards. This problem can be addressed through strategic planning for the nation’s economic and overall development

ASCE (2017). Infrastructure Report Card. Reston. VA.

Hashemi B., Iseley T., & Raulston J. Water Pipeline Renewal Evaluation Using AWWA Class IV CIPP, Pipe Bursting and Open-Cut. ASCE International Conference on Pipelines and Trenchless Technology. 2011.

Kaushal V. Green Manufacturing. Proc. National Seminar on New Horizons in Engineering and Technology, India. 2013.

Kaushal V. Earthquake Resistant Construction. Engineering Sciences International Research Journal. 2014; 2(1): pp. 185-187.

Santo Domingo J. W., Revetta R. P., Iker B., Gomez-Alvarez V., Garcia J., Sullivan J., & Weast J. Molecular Survey of Concrete Sewer Biofilm Microbial Communities. Biofouling. 2011; 27: pp. 993–1001.

Satoh H., Odagiri M., Ito T. & Okabe, S. Microbial Community Structures and In Situ Sulfate-Reducing and Sulfur-Oxidizing Activities in Biofilms Developed on Mortar Specimens in a Corroded Sewer System. Water Res. 2009; 43: pp. 4729-4739.

Kaushal V., & Sharma, V. Novel Composite Mix Based on Jute Fibres for Building Construction. Proc. International Conference on Redefining Textiles: Cutting Edge Technology of the Future (RTCT-2016), NIT Jalandhar, India. 2016.

Kaushal V., Iyer G., Najafi M., Sattler M., & Schug K. Review of Literature for Cured-in-Place Pipe (CIPP) Chemical Emissions and Worker Exposures. Proc. Transportation Research Board Annual Meeting, Washington, D.C. 2019.

Kaushal V., Najafi M. & Love J. Qualitative Investigation of Microbially Induced Corrosion of Concrete in Sanitary Sewer Pipe and Manholes. Proc. ASCE Pipelines 2018, Toronto, Canada. 2018: pp. 768-775.

Kaushal V., Najafi M., & Love J. A State-of-the-Art Review on Microbially Induced Corrosion of Concrete in Municipal Sewerage System. Journal of Pipeline Systems Engineering and Practice, ASCE (In-process). 2019.

Najafi M. & Gokhale S. Trenchless Technology Pipeline and Utility Design, Construction, and Renewal. McGraw-Hill, NY, 2005.

Najafi M. & Kim O.K. Life-Cycle-Cost Comparison of Trenchless and Conventional Open-Cut Pipeline Construction Projects. Proc. ASCE Pipelines Conference. 2004.

Najafi M., Sattler M., Schug K., Kaushal V., & Iyer, G. Evaluation of Potential Release of Organic Chemicals in the Steam Exhaust and Other Release Points during Pipe Rehabilitation Using the Trenchless Cured-In-Place Pipe (CIPP) Method. Final Report. 2018.

Roy D.M., Arjunan P. & Silsbee M.R. Effect of Silica Fume, Metakaolin, and Low-Calcium Fly Ash on Chemical Resistance of Concrete. Cem. Concr. Res. 2001; 31: pp. 1809–1813.

Kaushal, V. Influence of Jute Fibres on the Unconfined and Compressive Strength of Alkaline Soil. Journal of Civil Engineering and Environmental Technology. 2015; 2(4): pp. 335–338.

Kaushal V. & Guleria S. P. Geotechnical Investigation of Black Cotton Soils. International Journal of Advances in Engineering Sciences. 2015; 5(2): pp. 15–22.

Kaushal V. & Guleria S. P. Study of Tensile Strength and Mineralogical Behavior of Flyash-Lime-Gypsum Composite Reinforced with Jute Fibres. Proc. National Conference on Innovations without limits in Civil Engineering (IWLCE 2016), India. 2016.

Sabir B.B., Wild S. & Bai J. Metakaolin and Calcined Clays as Pozzolans for Concrete: A Review. Cem. Concr. Compos. 2001; 23: pp. 441–454.

Santo Domingo J. W., Revetta R. P., Iker B., Gomez-Alvarez V., Garcia J., Sullivan J., & Weast J. Molecular Survey of Concrete Sewer Biofilm Microbial Communities. Biofouling. 2011; 27: pp. 993–1001.

Satoh H., Odagiri M., Ito T. & Okabe S. Microbial Community Structures and In Situ Sulfate-Reducing and Sulfur-Oxidizing Activities in Biofilms Developed on Mortar Specimens in a Corroded Sewer System. Water Res. 2009; 43: pp. 4729–4739.

Senhadji Y., Escadeillas G., Mouli M., Khelafi H. & Benosman. Influence of Natural Pozzolan, Silica Fume and Limestone Fine on Strength, Acid Resistance and Microstructure of Mortar. Powder Technol. 2014; 254: pp. 314–323.

Sharma J., Najafi M., Marshall D., Kaushal V., & Hatami M. Development of a Model for Estimation of Buried Large Diameter Thin Walled Steel Pipe Deflection due to External Loads. (Accepted), Journal of Pipeline Systems Engineering and Practice, ASCE. 2019; 10.

Shetti A.P. & Das B.B. Acid, Alkali and Chloride Resistance of Early Age Cured Silica Fume Concrete. Advances in Structural Engineering: Materials; Springer: New Delhi, India. 2015; 3: pp. 1849–1862.

Sublette K.L., Kolhatkar R. & Raterman K. Technological Aspects of the Microbial Treatment of Sulfide-Rich Wastewaters: A Case Study. Biodegradation. 1998; 9: pp. 259–271.

Kaushal V., Najafi M., Sattler M., & Schug K. Evaluation of Potential Release of Organic Chemicals in the Steam Exhaust and Other Release Points during Pipe Rehabilitation Using the Trenchless Cured-In-Place Pipe (CIPP) Method. Proc. North American Society for Trenchless Technology (NASTT) No-Dig Conference, Chicago, IL. 2019.

Kaushal V., Najafi M., Sattler M., & Schug K. Review of Literature on Chemical Emissions and Worker Exposures Associated with Cured-In-Place Pipe (CIPP) Installation. Proc. ASCE Pipelines 2019, Nashville, TN. 2019.

Sugio T., White K.J., Shute E., Choate D. & Blake R.C. Existence of Hydrogen. 1992.

Sulfide. Ferric Ion Oxidoreductase in Iron-oxidizing Bacteria. Appl. Environ. Microbiol. 58: pp. 431–433.

Tabesh A. Najafi M. & Kaushal V. Environmental Impact Assessment of Truck, Railroad, and Underground Freight Transportation System. Proc. International Symposium on Underground Freight Transportation (ISUFT-2018), Beijing, China. 2018.

U.S. DOT. The State of the National Pipeline Infrastructure. A Report. 2015.