Strength testing of thermal welded PVC geomembrane



Strength testing of thermal welded PVC geomembrane field seams using non-destructive air channel methods
 

by Rohe, Fred P.
and Rohe, Daniel S.

Environmental Protection, Inc.


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Keywords: Geosynthetics, PVC, PVC Geomembrane, Quality Control, Thermal Welding, Air Channel, ASTM D7177, Case Studies, Closure, Final Covers, Geotechnical Design, Innovative Technologies, Landfill Construction, Landfill Design, Landfill Gas Management
 

ABSTRACT:  Air channel strength testing of dual track thermal welds of PVC geomembranes has been developed to provide quality assurance for the full length of PVC geomembrane field welds, eliminating the need for cutting holes in the liner to perform destructive peel testing.  The testing method was evaluated by ASTM Committee D-35 and was adopted as ASTM D 7177 Standard Specification in June 2005 and has been published in time for use in the 2006 construction season.  This paper will present a detailed case history of the installation quality control and engineering quality assurance programs implemented on the 2 million square foot (185,000 M2) PVC geomembrane closure installed on the Georgia Pacific Paper mill sludge landfill in Parchment, MI, USA.  This first of its kind PVC air channel strength testing Quality Control program was developed in conjunction with the Michigan Department of Environmental Quality and the design engineers at Blasland Bouck and Lee, Inc. (BB&L).  The 30 mil PVC geomembrane was installed using dual track thermal welding and over 10 kilometers (6 Miles) of field seams were air channel tested for seam peel strength and continuity.  The success of this project has provided the basis for implementing this new technology for testing PVC geomembrane field welds and for developing an ASTM standard test method for the geomembrane industry.


1     Introduction

In 1990, the author began experimenting with thermal welding of PVC geomembranes.  The original motivation was to develop installation and welding methods that would extend the construction season in the cold northern climates of the USA.  Subsequent projects such as the Coachella Canal Underwater Lining Prototype clarified the need for a more rapid and faster curing method for welding PVC than the chemical or adhesive methods being used at the time.  With the advent of wedge welding of HDPE geomembranes, engineers became more comfortable with that method than extrusion welding.  Further refinement of the dual track process made it the method of choice for many QC firms.  In the mid 90’s thermal welding of PVC was somewhat of a novelty in the USA, but eventually caught on with installers.  Many used a single wedge machine and continued to use old fashioned air lance testing to verify seam integrity.

During this period, welding equipment manufacturers also began developing smaller, lighter weight machines that were better suited for welding highly flexible materials like PVC.  Most of the wedge machines used a single wedge approximately one inch wide.  Hot air machines were introduced that used a wedge or a nozzle for producing single or double seams.  The authors began experimenting and developing procedures to dual track weld PVC so that air channel testing could also be done on PVC.   Early attempts with the heavier machines used on HDPE were less than desirable.  There were many difficulties making long seams in the flexible PVC.  Light weight hot air welders that could easily adjust nip roller pressure proved to be the solution for making high quality PVC seams.

Continued experimentation with air channel testing on 30 mil PVC geomembrane projects produced mixed, but encouraging results.  Testing the air channel using methods similar to those used on HDPE was the starting point.  However, in the hot summer months, air channel testing flexible PVC at high ambient temperatures with the high air pressures required for the more rigid HDPE proved to be more damaging to good PVC seams than it did to find flaws.  Other ideas needed to be explored.

2        Research

In 2001 the PVC Geomembrane Institute funded basic research by TRI Environmental on the thermal welding temperature variables for PVC geomembrane.  This initial research lead to the conclusion that air channel testing of PVC geomembrane dual track welds could provide accurate information about the peel strength for the full length of the weld.

This research was continued in early 2002 by TRI to find the optimum welding conditions for PVC and to further asses the author’s theory that air channel testing of PVC dual track welds could confirm the minimum peel strength of the weld and eliminate the need to cut any destructive samples.

In order to provide the basic information, dual track hot air welding was used on 54 different PVC seam variations.  In order to establish the variable parameters, three different welding temperatures with three different welding speeds were selected.  These were performed on materials at three different ambient temperatures.  These 27 different combinations were used to weld 30 mil and 40 mil PVC geomembrane.  To further broaden the data base, the same variations were duplicated using hot wedge welding on 30 and 40 mil PVC, bring the total to 108 sample variations.



Figure 1.)  PVC Air channel burst testing

 

Each seam was peel and shear tested in the laboratory according to ASTM D 6392. Each seam was made long enough to allow air channel testing of each of these seam combinations to be conducted at three different ambient test temperatures.  This allowed for analysis of the effect of ambient temperature on each of the air channel tests for different weld variables.  Each seam section was tested until burst (Fig.1).  The results of the testing provided broad information about the effect of ambient sheet temperature on the air channel test as it relates to the peel strength of each weld.
 

Figure 2.) Effect of ambient sheet temperature on PVC seam peel strength.


The data generated did not include low temperature tests, so a second battery of samples was prepared during the winter of 2003 to provide more accurate temperature requirements at ambient temperatures below 80ºF (27ºC).   When this data was included in the research, it became apparent that the relationship of ambient temperature and test pressure was linear rather than the curve in Fig. 2.  Further modifications of the test pressure/ambient temperature chart will be developed in the future.

3        Case history

The Georgia-Pacific paper mill in Parchment, MI was unable to obtain LLDPE geomembrane for a landfill closure project scheduled for installation in the late summer of 2002.  Engineers from Blasland Bouck & Lee (BB&L) were encouraged to consider using PVC geomembrane as a substitute for the 40 mil LLDPE textured both sides, and still meet all permit requirements.  Environmental Protection, Inc. (EPI) worked with BB&L and the Michigan Department of Environmental Quality to provide all the information necessary to revise the specifications and permit applications.  Revisions were made to the CQC/CQA plan to insure that all materials and welding methods would meet MI-DEQ permit requirements.

Friction angle testing was conducted on 30 mil smooth PVC geomembrane samples with the soils encountered at the site.  Smooth PVC met all the factors of safety requirements for slope stability with the soils on this project.  There was no need to use a textured material because the smooth PVC soil interface friction angles were above the minimum requirements for the project.

Figure 3.)  PVC Panel layout of Type III cell


The project consisted of two cells.  The Type II cell was an ash fill requiring 55,000 M2 of 30 mil PVC liner.   The liner was placed directly on the fine, black ash material compacted on the 3/1 slopes of the cell.  The second area was a Type III waste cell that had been covered with two feet of sand material by Terra Contracting, LLC, the prime contractor on the project.  This cell required 130,000 M2 of PVC.  The PVC liner would also be placed directly on the sand layer already placed over the Type III waste on slopes varying from 5/1 up to 3/1 shown in the photo (Figure 4).




Figure 4.)  Arial view of Type III cell PVC cap.


The Type II cell required 32 panels to cover the 55,000 M2 (598,200 sq. ft.) footprint.  2,500 M (8,200 lineal ft.) of field seam was required to seal the panels together on the 3/1 slopes of the waste pile.  Installation and thermal welding of liner started in September, even before fabrication of all the material for the cell was completed.  The MI-DEQ requirements for weld testing for this project included trial welds from each machine at the start and end of each welding session.  That meant trial welds needed to be tested in shear and peel at start up in the morning, before shut down at mid day, at start up again after any break in welding (i.e. lunch), and finally again before shut down of the welder at the end of the day.  Only one sample for destructive testing of shear and peel strength would be removed for independent laboratory testing each day that welding was performed, no matter how much field seam was welded that day.

All field seams were also to be non-destructively air channel tested (Fig. 5) according to established levels for air pressure and sheet temperature.  Based on research previously completed by EPI and the PGI, the installer was able to verify that peel strength exceeded the minimum requirement of 15 lb/in (2.6 kN/m) width for the full length of EVERY field seam.

Figure 5.)  Inflated PVC air channel test


The much larger Type III cell (Fig. 3 & 4) required 72 prefabricated panels to cover the 130,000 M2 (1,406,345 sq. ft.) waste pile.  The majority of the panels for both cells were 100 feet wide and 200 feet long.  Over 7 km (23,000 lineal feet) of field seam were required to weld the panels together.  While 4+ miles of field welding may seem like a huge number, this is 70% less than would have been required with LLDPE.  Air channel testing of the dual track PVC welds also eliminated 75% of the destructive test sampling that would have been required on this project (>200 sample holes for polyethylene).

Ambient temperatures during construction of the Type II cell cap varied from 65° - 92°F (18 - 33º C).  Sheet temperatures varied from 65° to 145° F (18-62º C) during welding operations.   The Type III cell cap was constructed in October and ambient temps ranged from 82°F down to 36°F (28–2ºC).  Sheet temperatures also varied greatly from a high of 120°F down to 36°F (49-2ºC).  Welder temperatures were set between 700° and 750°F (380 - 400ºC) and welder speeds ranged from 5 to 8 feet per minute (1.5–2.5 M/min), depending on sheet temperatures.

There were no destructive test failures on this project.  The combination of rigorous trial weld testing and air channel testing of every field seam resulted in confidence that every inch of seam exceeded minimum strength specifications.  There were also no air channel test failures due to below standard peel strength.  Air channel test failures were confined to holes in "T" seams where the loose flap of an intersecting field seam had not been trimmed properly.


4        ASTM D 7177 standard test method

In June 2003 EPI introduced the first draft of a standard specification for air channel testing of PVC thermal dual track welds based on the research completed and on actual field experience with welding and air channel testing large scale projects using PVC.  The process of ASTM peer review was completed in June of 2005 and ASTM D 7177 Standard Specification for Air Channel Evaluation of Polyvinyl Chloride (PVC) Dual Track Seamed
 

Sheet Temp ºC

Sheet Temp ºF

Air Pressure
KPa

Air Pressure
PSI

4.5

40

414

60

7

45

386

56

10

50

358

52

13

55

324

47

15.5

60

290

42

18

65

276

40

21

70

248

36

24

75

234

34

26.5

80

200

29

29.5

85

186

27

32

90

172

25

35

95

165

24

37.5

100

152

22

40.5

105

138

20

43.5

110

131

19

Figure 6.)  Pressure required to verify 15 lb/in (2.6 kN/m) seam peel strength for PVC (per PGI-1104)
 

Geomembranes became a reality. This standard is now available for design engineers, owners and installers to accurately test PVC geomembrane seams.


5        Conclusions

Hot air welders have a distinct advantage with PVC in that they do not produce a buildup of burnt material on a wedge that can then scrape off and be deposited in the seam, causing inconsistencies in seam peel strength.  Overall weld quality is superior with hot air welders than with current wedge welder technology for PVC geomembranes.

Air blowing from the nozzle into the seam from hot air welders also removes dirt, debris and moisture prior to melting the material, creating a more consistent weld in PVC.

Air channel testing of PVC geomembranes has developed to the level that it is possible to verify the peel strength of 100% of the length of dual track welded PVC field seams.  This method also exposes failing portions of seams (no matter how small) that destructive testing does not identify.  When combined with an Electronic Leak Location Survey, it is now possible to test the strength of every cm of PVC field weld and every square cm of material.


References

ASTM D 7177 (2005). “Standard Specification for Air Channel Evaluation of Polyvinyl Chloride (PVC) Dual Track Seamed Geomembranes”, American Society for Testing and Materials, West Conshohocken, Pennsylvania, USA

Thomas, Richard W. (2002). “Thermally Bonded PVC Seams”, Phase II - The Effects of Welding Speed, Welding Temperature, and Sheet Temperature on the Peel Strength and Burst Strength of 30 mil and 40 mil PVC Double-Track Fusion Seams.

Thomas, Richard W., Stark, Timothy D., Choi, Hangseok, (2003). “Air channel testing of thermally bonded PVC seams”, Geosynthetics International Journal, Industrial Fabrics Association International, Vol. 10, No. 3, October 2003, pp 645-659

Stark, Timothy D., Choi, Hangseok, Thomas, Richard W. (2003). “Low temperature air channel testing of thermally bonded PVC geomembrane seams”, International Association of Geosynthetic Installers, Industrial Fabrics Association International, Vol. 4, Issue 1, Winter 2004, pp. 5-7.

Thomas, Richard W., Stark, Timothy D. (2003). “Reduction of destructive tests for PVC seams”, Geotechnical Fabrics Report, Vol 21, No 2, March 2003

Rohe, Fred P., (EPI) 2004. “PVC geomembrane liner placement underwater in an operating irrigation canal”, Proceedings IGS Peru, November 2004

ASTM D 6392 (1999). “Standard Test Method for Determining the Geomembrane Seams Produced using Thermo-Fusion Methods”, American Society for Testing and Materials, Vol. 04.09, West Conshohocken, Pennsylvania, USA, pp. 1311-1315.

PVC Geomembrane Institute (PGI), 2004. “PGI-1104 PVC Geomembrane Specification”, University of Illinois, Urbana, IL, January  2004.

 

 

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