Electrical liner integrity surveys, also known as leak location surveys are a post-installation quality control method of detecting leaks in geomembranes. Geomembranes are typically used for large-scale containment of liquid or solid waste. These electrical survey techniques are widely embraced as the state-of-the-art methods of locating leaks in installed geomembranes, which is imperative for the long-term protection of groundwater and the maintenance of water resources. Increasingly specified by environmental regulations, the methods are also applied voluntarily by many site owners as responsible environmental stewards and to minimize future liability.
Electrical liner integrity surveys were initially developed at Southwest Research Institute through funding provided by the U.S. Environmental Protection Agency as a response to the need to control the quality of geomembrane installations. Three technical papers describing the method were published and presented by Southwest Research Institute in 1982. The first commercial adaptations and applications of the methods were in Chile (1984), the United States (1985), and Slovakia.
The first ASTM standard to address the methods was drafted in 2000 and accepted for publication in 2003.
The methods that can be used generally fall into two categories depending on whether or not the geomembrane is exposed or covered during the survey. ASTM D6747 [1] provides a standard guide for the selection of electrical detection techniques for various applications. All methods require an electrically conductive medium both above and below the geomembrane and electrical isolation of the survey area from the surrounding ground. Some design foresight may be required in order to ensure that an electrical liner integrity survey can be performed.
Specially formulated geomembranes with a conductive backing can enable the performance of a survey where there is no electrically conductive medium below the geomembrane, such as the primary geomembrane of double-lined facilities with only geonets or geocomposites between the primary and secondary geomembranes and where the ability to place water between the geomembranes is not possible on the slopes. Specially formulated conductive geotextiles are also available to enable electrical surveys for these applications.
There is some debate on the electrical conductivity of geosynthetic clay liners in the application of electrical liner integrity surveys. [2] The moisture content of geosynthetic clay liners is sufficient for the methods as the sheets leave the factory, however the sheets can become desiccated while they are placed in the field. This becomes a problem for encapsulated geosynthetic clay liners, located between the primary and secondary geomembranes, which cannot wick moisture from the underlying subgrade soil. Adding copper wires as part of the construction process allows the geosynthetic clay liner to conduct electricity in order to perform the survey.
The water puddle method (ASTM D7002), [3] the water lance method (ASTM D7703) [4] and the newly introduced arc testing method (ASTM D7953) are used for bare geomembranes. For the water puddle and water lance methods, water is sprayed onto the geomembrane, creating an electrically conductive layer above the geomembrane. A low voltage DC power source is applied to the water above the geomembrane and grounded to the earth below the geomembrane. The leak detection equipment features an ammeter in series with the applied potential circuit. The ammeter registers an increase in current in the presence of a leak, resulting in an audible tone and visual increase in the current level. The expected minimum sensitivity of the water-based bare geomembrane liner integrity methods is a one millimeter diameter circular leak. For the arc testing method, water is not required. A high voltage (Approximately 5000V-35000V) with a very low current is introduced above the geomembrane and grounded to the conductive layer below it. In the presence of a hole, an electrical arc is formed along with an audible alarm. Since the arc testing method is not dependent on water making good contact through the leak, it is more sensitive and comparatively easy to perform in most types of liner construction (ponds, Landfills, tanks etc.)than the water-based methods. The minimum sensitivity of the arc testing bare geomembrane liner integrity method is a pinhole leak.
For geomembranes with a conductive backing, spark testing can be performed (ASTM D7240). [5] For the spark testing method, water is not sprayed onto the exposed geomembrane. A high DC voltage is introduced across the geomembrane, creating a spark where the geomembrane contains a breach.
The dipole method (ASTM D7007 or ASTM D8265) [6] [7] is used for geomembranes covered with earthen materials or water. A high voltage DC power source is applied to the medium above the geomembrane and grounded to the soil underneath the geomembrane. Measurements of voltage potential are taken using a dipole probe in a grid pattern throughout the surface of the survey area. Hole locations can be pinpointed by a characteristic sine wave pattern in the voltage field across the location of a leak. Data collection and voltage mapping are often used with this method to provide quality assurance documentation and additional survey oversight. The sensitivity of the dipole survey method is highly dependent on site conditions such as the moisture content, depth and mineralogy of the cover material for soil-covered geomembranes and the electrical conductivity of solution-covered geomembranes. The expected minimum sensitivity for soil-covered geomembranes is 6.4 mm in diameter for up to 600 mm of earth material depth. The expected minimum sensitivity for water-covered geomembranes is 1.4 mm in diameter.
Electrostatic discharge (ESD) is a sudden and momentary flow of electric current between two electrically charged objects caused by contact, an electrical short or dielectric breakdown. A buildup of static electricity can be caused by tribocharging or by electrostatic induction. The ESD occurs when differently-charged objects are brought close together or when the dielectric between them breaks down, often creating a visible spark.
In electrical engineering, partial discharge (PD) is a localized dielectric breakdown (DB) of a small portion of a solid or fluid electrical insulation (EI) system under high voltage (HV) stress. While a corona discharge (CD) is usually revealed by a relatively steady glow or brush discharge (BD) in air, partial discharges within solid insulation system are not visible.
Geosynthetics are synthetic products used to stabilize terrain. They are generally polymeric products used to solve civil engineering problems. This includes eight main product categories: geotextiles, geogrids, geonets, geomembranes, geosynthetic clay liners, geofoam, geocells and geocomposites. The polymeric nature of the products makes them suitable for use in the ground where high levels of durability are required. They can also be used in exposed applications. Geosynthetics are available in a wide range of forms and materials. These products have a wide range of applications and are currently used in many civil, geotechnical, transportation, geoenvironmental, hydraulic, and private development applications including roads, airfields, railroads, embankments, retaining structures, reservoirs, canals, dams, erosion control, sediment control, landfill liners, landfill covers, mining, aquaculture and agriculture.
Waterproofing is the process of making an object or structure waterproof or water-resistant so that it remains relatively unaffected by water or resisting the ingress of water under specified conditions. Such items may be used in wet environments or underwater to specified depths.
Moisture vapor transmission rate (MVTR), also water vapor transmission rate (WVTR), is a measure of the passage of water vapor through a substance. It is a measure of the permeability for vapor barriers.
Geocomposite is a composition / combination of two or more geosynthetic materials to perform multiple number of geosynthetic functions for specific civil engineering application(s) the purpose of providing this composition is to minimize the application costs whereas the technical properties of the soil or the geotechnical structure are enhanced.
A geomembrane is very low permeability synthetic membrane liner or barrier used with any geotechnical engineering related material so as to control fluid migration in a human-made project, structure, or system. Geomembranes are made from relatively thin continuous polymeric sheets, but they can also be made from the impregnation of geotextiles with asphalt, elastomer or polymer sprays, or as multilayered bitumen geocomposites. Continuous polymer sheet geomembranes are, by far, the most common.
Geosynthetic clay liners (GCLs) are factory manufactured hydraulic barriers consisting of a layer of bentonite or other very low-permeability material supported by geotextiles and/or geomembranes, mechanically held together by needling, stitching, or chemical adhesives. Due to environmental laws, any seepage from landfills must be collected and properly disposed of, otherwise contamination of the surrounding ground water could cause major environmental and/or ecological problems. The lower the hydraulic conductivity the more effective the GCL will be at retaining seepage inside of the landfill. Bentonite composed predominantly (>70%) of montmorillonite or other expansive clays, are preferred and most commonly used in GCLs. A general GCL construction would consist of two layers of geosynthetics stitched together enclosing a layer of natural or processed sodium bentonite. Typically, woven and/or non-woven textile geosynthetics are used, however polyethylene or geomembrane layers or geogrid geotextiles materials have also been incorporated into the design or in place of a textile layer to increase strength. GCLs are produced by several large companies in North America, Europe, and Asia. The United States Environmental Protection Agency currently regulates landfill construction and design in the US through several legislations.
The Proctor compaction test is a laboratory method of experimentally determining the optimal moisture content at which a given soil type will become most dense and achieve its maximum dry density. The test is named in honor of Ralph Roscoe Proctor, who in 1933 showed that the dry density of a soil for a given compactive effort depends on the amount of water the soil contains during soil compaction. His original test is most commonly referred to as the standard Proctor compaction test; his test was later updated to create the modified Proctor compaction test.
A landfill liner, or composite liner, is intended to be a low permeable barrier, which is laid down under engineered landfill sites. Until it deteriorates, the liner retards migration of leachate, and its toxic constituents, into underlying aquifers or nearby rivers, causing potentially irreversible contamination of the local waterway and its sediments.
The Comparative Tracking Index (CTI) is used to measure the electrical breakdown (tracking) properties of an insulating material. Tracking is an electrical breakdown on the surface of an insulating material wherein an initial exposure to electrical arcing heat carbonizes the material. The carbonized areas are more conductive than the pristine insulator, increasing current flow, resulting in increased heat generation, and eventually the insulation becomes completely conductive.
Cellular confinement systems (CCS)—also known as geocells—are widely used in construction for erosion control, soil stabilization on flat ground and steep slopes, channel protection, and structural reinforcement for load support and earth retention. Typical cellular confinement systems are geosynthetics made with ultrasonically welded high-density polyethylene (HDPE) strips or novel polymeric alloy (NPA)—and expanded on-site to form a honeycomb-like structure—and filled with sand, soil, rock, gravel or concrete.
A geonet is a geosynthetic material similar in structure to a geogrid, consisting of integrally connected parallel sets of ribs overlying similar sets at various angles for in-plane drainage of liquids or gases. Geonets are often laminated with geotextiles on one or both surfaces and are then referred to as drainage geocomposites. They are competitive with other drainage geocomposites having different core configurations.
Final cover is a multilayered system of various materials which are primarily used to reduce the amount of storm water that will enter a landfill after closing. Proper final cover systems will also minimize the surface water on the liner system, resist erosion due to wind or runoff, control the migrations of landfill gases, and improve aesthetics.
Electronic components have a wide range of failure modes. These can be classified in various ways, such as by time or cause. Failures can be caused by excess temperature, excess current or voltage, ionizing radiation, mechanical shock, stress or impact, and many other causes. In semiconductor devices, problems in the device package may cause failures due to contamination, mechanical stress of the device, or open or short circuits.
Geomembranes are thin plastic sheets that are essentially impervious and are used to prevent leakage from liquid or solid-storage facilities. Geomembranes are frequently referred to as Flexible Membrane Liners (FMLs) in environmental regulations, such as in Subtitle D of the Resource Conservation and Recovery Act.
Transformer oil, a type of insulating and cooling oil used in transformers and other electrical equipment, needs to be tested periodically to ensure that it is still fit for purpose. This is because it tends to deteriorate over time. Testing sequences and procedures are defined by various international standards, many of them set by ASTM. Transformer oil testing consists of measuring breakdown voltage and other physical and chemical properties of samples of the oil, either in a laboratory or using portable test equipment on-site.
Jean-Pierre Giroud is a French geotechnical engineer and a pioneer of geosynthetics since 1970. In 1977, he coined the words "geotextile" and "geomembrane", thus initiating the "geo-terminology". He is also a past president of the International Geosynthetics Society, member of the US National Academies, and Chevalier de la Légion d'Honneur.