Understanding of Subsurface Cavity Mechanism due to the Deterioration of Buried Pipe

Buried pipe design requires knowledge about the fill to design the backfill structure. The interaction between the backfill envelope and the pipe impacts the structural performance of the buried pipe. The backfill material and compaction level respond to the backfill’s overall strength and, therefore, for pipe-soil interaction. The strength of backfill material is described in terms of modulus of soil reaction E’ and constrained modulus Eode. As the E’ is an empirical parameter, the Eode can be measured in the laboratory by performing the oedometer tests. In this study, we have performed extensive oedometric tests on five types of anthropogenic materials (AM). Three of them are construction and demolition materials (C–D materials) namely, recycled concrete aggregate (RCA), crushed brick (CB), and recycled asphalt pavement (RAP). Two of them are industrial solid wastes (ISW) namely, fly ash and bottom slag mix (FA + BS) and blast furnace slag (BFS). The results of the tests revealed that AM behaves differently from natural aggregates (NA). In general, the Eode value for AM is lower than for NA with the same gradation. Despite that, some of AM may be used as NA substitute directly (RCA or BFS), some with special treatment like CB and some with extra compaction efforts like RAP or FA + BS.

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Development of a prototype for modelling soil–pipe interaction and its application for predicting uplift resistance to buried pipe movements in sand

Canadian Geotechnical Journal ◽

10.1139/cgj-2017-0559 ◽

2018 ◽

Vol 55 (10) ◽

pp. 1451-1474 ◽

Cited By ~ 5

Author(s):

Yousef Ansari ◽

George Kouretzis ◽

Scott W. Sloan

Keyword(s):

Scale Effects ◽

Reaction Force ◽

Failure Surface ◽

Relative Displacement ◽

Published Data ◽

Buried Pipe ◽

Image Velocimetry ◽

Close Range ◽

Uplift Resistance

This paper presents a testing rig for measuring the reactions on rigid pipes buried in sand during episodes of relative displacement. Following a detailed presentation of the 1g prototype, the test preparation procedure, and the characterization of the test sand’s shear strength and dilation potential under the low confining stresses pertinent to the problem, the paper focuses on the workflow devised to obtain accurate measurements of friction and arching effects, and accordingly normalize them to account for scale (stress level) effects. Emphasis is put on demonstrating the effectiveness of the sand deposition method for accurately controlling the density of the sample, and on quantitatively assessing its uniformity. Measurements obtained during a series of uplift tests, including reaction force – pipe displacement curves and images of the developing failure surface, facilitated by particle image velocimetry and close-range photogrammetry techniques, are compared against published data and analytical methods. The results lead to the development of a new simplified formula for calculating the uplift resistance to buried pipe movements in sand: capable of accounting for scale effects, yet simple enough to be used for the analysis of pipes in practice.

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Analysis the Influence of the Thermal Diffusivity of the Soil around Buried Pipe on Soil Physical Property

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.805-806.552 ◽

2013 ◽

Vol 805-806 ◽

pp. 552-556

Author(s):

Ying Xu ◽

Xiao Yan Liu

Keyword(s):

Temperature Field ◽

Thermal Diffusivity ◽

Soil Temperature ◽

Temperature Drop ◽

Physical Property ◽

Field Soil ◽

Buried Pipeline ◽

Buried Pipe ◽

Soil Physical Property ◽

Natural Temperature

In chilliness area, the temperature drop of oil in buried pipeline is affected by soil temperature field, and the thermal diffusivity is one of the main of physical property the soil, which affects the temperature drop of oil directly. This paper introduced the test principle of the thermal diffusivity of soil, and researched the influence of thermal diffusivity of soil on the soil physical property, such as soil natural temperature field, soil frozen days, depth of freezing and temperature delay, which can offer theory support for the calculation of hot oil temperature drop in buried pipeline.

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Quasi-Three-Dimensional Steady-State Analytic Solution for Melting or Freezing Around a Buried Pipe in a Semi-Infinite Medium

Journal of Heat Transfer ◽

10.1115/1.3247386 ◽

1985 ◽

Vol 107 (1) ◽

pp. 245-247 ◽

Cited By ~ 5

Author(s):

Guo-Ping Zhang ◽

L. M. Jiji ◽

S. Weinbaum

Keyword(s):

Steady State ◽

Analytic Solution ◽

Three Dimensional ◽

Infinite Medium ◽

Buried Pipe

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Thawing of Permafrost Beneath a Buried Pipe

Journal of Canadian Petroleum Technology ◽

10.2118/77-04-05 ◽

1977 ◽

Vol 16 (04) ◽

Cited By ~ 1

Author(s):

V.J. Lunardini

Keyword(s):

Buried Pipe

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Particle Shape Effect on Macroscopic Behaviour of Underground Structures: Numerical and Experimental Study

Studia Geotechnica et Mechanica ◽

10.2478/sgem-2014-0028 ◽

2015 ◽

Vol 36 (3) ◽

pp. 67-74 ◽

Cited By ~ 1

Author(s):

Krzysztof Szarf ◽

Gael Combe ◽

Pascal Villard

Keyword(s):

Particle Shape ◽

Load Transfer ◽

Mechanical Performance ◽

Flexible Structures ◽

Discrete Element ◽

Grain Structure ◽

Experimental Investigations ◽

Shape Effect ◽

Underground Structures ◽

Buried Pipe

Abstract The mechanical performance of underground flexible structures such as buried pipes or culverts made of plastics depend not only on the properties of the structure, but also on the material surrounding it. Flexible drains can deflect by 30% with the joints staying tight, or even invert. Large deformations of the structure are difficult to model in the framework of Finite Element Method, but straightforward in Discrete Element Methods. Moreover, Discrete Element approach is able to provide information about the grain-grain and grain-structure interactions at the microscale. This paper presents numerical and experimental investigations of flexible buried pipe behaviour with focus placed on load transfer above the buried structure. Numerical modeling was able to reproduce the experimental results. Load repartition was observed, being affected by a number of factors such as particle shape, pipe friction and pipe stiffness.

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Guided Wave Testing: Maximizing Buried Pipe Corrosion Knowledge From Each Excavation

Volume 1: Codes and Standards ◽

10.1115/pvp2012-78561 ◽

2012 ◽

Author(s):

Andy Crompton ◽

Roger Royer ◽

Mark Tallon ◽

Stephen F. Biagiotti

Keyword(s):

Guided Wave ◽

Piping System ◽

Case Histories ◽

Direct Examination ◽

Buried Pipe ◽

Industry Standard ◽

Limited Effectiveness ◽

Wall Loss ◽

Assurance Process ◽

Non Destructive

Excavation and Direct Examination of buried piping using conventional non-destructive examination (NDE) has been the traditional inspection approach for decades and remains the only quantitative method for piping evaluations in plants when internal in-line inspection tools cannot be used due to geometry or other constraints. This “difficult to assess” piping presents many challenges, including limited effectiveness of traditional indirect inspection tools, high cost and operational concerns associated with excavations, and the ability to evaluate only a small sampling of a piping system. Many inspection technologies exist for buried pipe assessments; however, no indirect techniques provide the ability to yield quantitative wall loss values suitable for ASME fitness for service calculations beyond what’s exposed in the excavation. An evolving technology, guided wave testing (GWT), has many applications including the ability to provide assessment information beyond the excavation. In this paper, the application of GWT for buried piping inspection will be discussed. We will review: principles behind its operation; the competitive technologies on the market; challenges for the technology; management of data within the Electric Power Research Institute (EPRI) industry standard buried pipe database (BPWorks™ 2.0); trending; case histories showing how GWT can be used to extend the knowledge gained during an excavation by screening adjacent areas for more significant corrosion than observed in the excavated and exposed area; coupling GWT results with other inspection technologies to gain an enhanced interpretation of the overall condition of the line; and how to incorporate this data into an effective structural and/or leakage integrity program as part of the reasonable assurance process.

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