Structural Performance of Buried Profile-Wall High-Density Polyethylene Pipe and Influence of Pipe Wall Geometry

1998 ◽  
Vol 1624 (1) ◽  
pp. 206-213 ◽  
Author(s):  
A. P. Moser
Keyword(s):  
High Density Polyethylene ◽  
Pipe Wall ◽  
Unit Length ◽  
High Density ◽  
Structural Performance ◽  
Pipe Material ◽  
Performance Limits ◽  
Performance Limit ◽  
Section Modulus ◽  
Localized Buckling

Tests conducted on buried high-density polyethylene pipes are reported. Pipes were loaded until buckling occurred to determine performance limits and the influence of profile parameters on structural performance. These profile parameters include rib height, rib spacing, wall thicknesses, wall area per unit length, unsupported profile section length, and stiffness. In a profile-wall pipe, by design, as much pipe material as possible is placed away from the neutral axis in the form of inside or outside walls or in ribs to minimize the use of pipe material by increasing the section modulus of the pipe wall. For the products tested, the data show that the profile section acts as a unit as designed only up to a point. High earth loads will induce buckling in the profile wall of the pipe. For adequate safety, the pipe design should include sufficient plastic between the inner and outer walls or between the ribs to carry shear and to ensure that the profile section indeed acts as a unit. Each product exhibits different performance limits, and these limits occur at different loads and deflections. Performance limits are often deflection related, but for high soil densities they are load related. For profile-wall pipe, localized or general buckling is usually the lowest performance limit. The cross-sectional area per unit length and the individual wall component thickness should be sufficient to resist localized buckling. It should be noted that for some profile-wall pipes, controlling vertical deflection may not control localized buckling as a performance limit. Performance limits for the pipes tested are reported.

Structural Performance of Storm Water Detention System with Bundled High-Density Polyethylene Pipes

2003 ◽  
Vol 1845 (1) ◽  
pp. 182-187
Author(s):  
Steven L. Folkman ◽  
A. P. Moser
Keyword(s):  
High Density Polyethylene ◽  
High Density ◽  
Silty Sand ◽  
Storm Water ◽  
Crushed Stone ◽  
Structural Performance ◽  
Soil Columns ◽  
Polyethylene Pipes ◽  
Hdpe Pipes

Buried parallel pipes are used for storm retention systems. Traditional retention-detention systems have spaced parallel pipes that permit soil columns between pipes. A new design allows for the parallel pipes to be placed side by side in contact with each other. The performance of such a system of bundled high-density polyethylene (HDPE) pipes that is subjected to vertical earth loads is reported. This bundled system consists of parallel HDPE pipes wrapped with a geogrid and a geofabric. The actual loads ranged from shallow cover to vertical loads equivalent to 55 ft (16.8 m) of cover. The embedment soil selected for the research was a silty sand. This soil was selected because its structural qualities are generally considered to be the least acceptable for these types of applications. The soil that typically would be specified is a crushed stone. Therefore, the results from the tests are conservative. Structural performance is reported, and photographs present the pipes in the bundled system during installation and after subjection to earth loads. Load-deflection curves for the pipes in the system are also given.

Structural Performance of Fusion Weld Based on Weld Parameters and Strain Rate in High-Density Polyethylene

2021 ◽  
Vol 50 (2) ◽  
pp. 20210139
Author(s):  
Ahmed Faraz ◽  
Behzad Ahmed Zai ◽  
Salman Nisar ◽  
Asif Mansoor ◽  
Rashid Ali
Keyword(s):  
Strain Rate ◽  
High Density Polyethylene ◽  
High Density ◽  
Structural Performance ◽  
Weld Parameters ◽  
Fusion Weld

Tensile Stress-Strain Properties and Elastic Modulus of PE 4710 Cell Classification 445574C High Density Polyethylene Pipe Material

2013 ◽  
Author(s):  
Timothy M. Adams ◽  
Jie Wen ◽  
Shawn Nickholds ◽  
Douglas Munson
Keyword(s):  
Elastic Modulus ◽  
High Density Polyethylene ◽  
Tensile Testing ◽  
Axial Direction ◽  
Tensile Tests ◽  
High Density ◽  
Pipe Material ◽  
Yield Strain ◽  
Cell Classification ◽  
Hdpe Pipe

For corroded piping in low temperature systems replacement of buried carbon steel pipe with high density polyethylene (HDPE) pipe is a cost-effective solution. The ASME Boiler and Pressure Vessel Code, Section III, Division 1, Code Case N755-1 currently permits the use of HDPE in buried Safety Class 3 piping systems. This paper presents the results of tensile testing of PE 4710 cell classification 445574C pipe compliant with the requirements of Code Case N755-1. This information was developed to support and provide a strong technical basis for tensile properties of HDPE pipe. The data may also be useful for applications of HDPE pipe in commercial electric power generation facilities and chemical, process, and waste water plants via its possible use in the B31 series piping codes. The paper provides values for yield stress, yield strain, ultimate strain, and elastic modulus. The standard tensile tests were conducted consistent with the requirements of ASTM D638-10. Specimens were cut in the axial direction from cell composition PE 4710 cell classification 445574C HDPE piping spools. In addition, the results are compared to previous tensile testing conducted on the PE 3608 cell classification 345464C and PE 4710 cell classification 445474C HDPE materials.

Structural and Hydraulic Performance of 1500-mm Smooth-Interior High-Density Polyethylene Pipe in Soil Cell

1997 ◽  
Vol 1594 (1) ◽  
pp. 200-207
Author(s):  
Victoria Daley
Keyword(s):  
High Density Polyethylene ◽  
Flow Characteristics ◽  
Hydraulic Performance ◽  
High Density ◽  
Structural Performance ◽  
Maximum Increase ◽  
Pipe Surface ◽  
Polyethylene Pipe ◽  
Cell Test ◽  
Geometric Changes

Soil cell tests have been used for decades to evaluate the structural performance of a variety of pipes. The structural performance of a 1500-mm (60-in.)-diameter, corrugated-exterior, smooth-interior high-density polyethylene pipe in a soil cell with two different backfill strengths is presented, and the results are compared with the values predicted theoretically. Specifiers demand assurance of the long-term hydraulic performance of smooth-interior corrugated polyethylene pipe. Fortunately, a mathematical model that allows for the estimation of the Manning value by using measurable pipe dimensions and flow characteristics is available. A discussion of the geometric changes in the interior pipe surface measured during the soil cell test is included, and an estimate of the resulting Manning values is provided. The results indicated a maximum increase in Manning values of approximately 3 or 10 percent, depending on backfill, for pipe buried within current industry recommendations for cover height.

Parametric study of buried steel and high density polyethylene gas pipelines due to oblique-reverse faulting

2015 ◽  
Vol 42 (3) ◽  
pp. 178-189 ◽  
Author(s):  
Fayaz Rahimzadeh Rofooei ◽  
Himan Hojat Jalali ◽  
Nader Khajeh Ahmad Attari ◽  
Hadi Kenarangi ◽  
Masoud Samadian
Keyword(s):  
High Density Polyethylene ◽  
Numerical Study ◽  
High Density ◽  
Pipe Diameter ◽  
Pipeline System ◽  
Burial Depth ◽  
Reverse Fault ◽  
Pipe Material ◽  
Reverse Faulting ◽  
Hdpe Pipes

A numerical study is carried out on buried steel and high density polyethylene (HDPE) pipelines subjected to oblique-reverse faulting. The components of the oblique-reverse offset along the horizontal and normal directions in the fault plane are determined using well-known empirical equations. The numerical model is validated using the experimental results and detailed finite element model of a 114.3 mm (4″) steel gas pipe subjected to a reverse fault offset up to 0.6 m along the faulting direction. Different parameters such as the pipe material, the burial depth to the pipe diameter ratio (H/D), the pipe diameter to wall thickness ratio (D/t), and the fault–pipe crossing angle are considered and their effects on the response parameters are discussed. The maximum and minimum compressive strains are observed at crossing angles of 30° and 90°, respectively. It is found that the dimensionless parameters alone are not sufficient for comparison purposes. Comparing steel and HDPE pipes, it is observed that HDPE pipes show larger compressive strains due to their lower strength and stiffness. For both steel and HDPE pipes, peak strains increase with increasing D/t and H/D ratio for a constant pipe diameter and fault offset. For a given H/D ratio, compressive strains increase with increasing D/t ratio in HDPE pipes, while in steel pipes considered in this study, this effect is negligible. Finally, the peak strains of the pipes are compared to those suggested by Canadian Standard Association for Oil and Gas Pipeline System, CSA Z662.

Determination of Material Damping Values for High Density Polyethylene Pipe Materials

2012 ◽  
Author(s):  
Douglas Munson ◽  
Timothy M. Adams ◽  
Siegrid Hall
Keyword(s):  
Carbon Steel ◽  
High Density Polyethylene ◽  
Seismic Analysis ◽  
High Density ◽  
Steel Pipe ◽  
Pipe Material ◽  
Material Damping ◽  
Labor Costs ◽  
Polyethylene Pipe ◽  
Service Water

For corroded piping in low temperature systems, such as service water systems in nuclear power plants, replacement of carbon steel pipe with High Density Polyethylene pipe is a cost-effective solution. Polyethylene pipe can be installed at much lower labor costs than carbon steel pipe and High Density Polyethylene pipe has a much greater resistance to corrosion. This paper presents the results of Electric Power Research Institute sponsored testing to determine material damping values for High Density Polyethylene pipe material. This was determined by experimental methods using the log decrement approach. Cantilevered beam samples were deflected, released and the resulting free vibration response was recorded. The possible relationship of the damping value to the natural frequency and the stress level of the test samples is also studied. The results of the testing are presented along with suggested damping values to be used in the seismic analysis of High Density Polyethylene piping.

Development of Crack Growth Curves and Correlation to Sustained Pressure Test Results for Cell Classification 445574C High Density Polyethylene Pipe Material

2013 ◽  
Author(s):  
Timothy M. Adams ◽  
Jason Hebeisen ◽  
Jie Wen ◽  
Douglas Munson
Keyword(s):  
Crack Growth ◽  
High Density Polyethylene ◽  
Failure Time ◽  
Slow Crack Growth ◽  
Growth Curves ◽  
High Density ◽  
Pipe Material ◽  
Test Results ◽  
Cell Classification ◽  
Failure Times

Code Case N755-1 of the ASME Boiler and Pressure Vessel Code, Section III, Division 1 Code currently permits the use of high density polyethylene (HDPE) in buried Safety Class 3 piping systems. There have been concerns with the Slow Crack Growth (SCG) of HDPE emanating from scratches that may occur during fabrication or installation. The possible use of tensile coupon tests for determining the life span of the pipe with surface scratches could provide a more cost effective testing method than does the use of sustained pressurized crack pipe tests. This paper presents the results of further investigation into the SCG rates of notched PE 4710 HDPE pipe made from a cell classification 445574C bimodal resin. The da/dt versus KI curves were developed from notched coupon testing. Standard fracture methods were then used to predict the failure time of the notched pressurized pipe specimens subjected to long-term hydraulic stress. The results for the SCG depth of the externally notched sustained pressurized pipe tests are provided along with the notched coupon test results. The actual failure times of the notched pressurized pipe tests are compared to the predicted failure times for the same specimens.

scholarly journals Structural performance of poultry eggshell derived hydroxyapatite based high density polyethylene bio-composites

Heliyon ◽  
2019 ◽  
Vol 5 (10) ◽  
pp. e02552 ◽  
Author(s):  
Isiaka Oluwole Oladele ◽  
Okikiola Ganiu Agbabiaka ◽  
Adeolu Adesoji Adediran ◽  
Akeem Damilola Akinwekomi ◽  
Augustine Olamilekan Balogun
Keyword(s):  
High Density Polyethylene ◽  
High Density ◽  
Structural Performance
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