GEOTEXTILES
1. INTRODUCTION
According to
the historical record, it is believed that the first applications of
geotextiles were woven industrial fabrics used in 1950’s. One of the earliest
documented cases was a waterfront structure built inFlorida in 1958. Then, the first nonwoven
geotextile was developed in 1968 by the Rhone Poulence company in France. It was a comparatively thick
needle-punched polyester, which was used in dam construction in France during 1970.
In fact, the
geotextile is one of the members of the geosynthetic family. Those members
include the following items
1. Geogrids
- Geonets
- Geotextiles
- Geomembranes
- Geosynthetic Clay Liners
- Geopipe
- Geocomposites
What is geotextile?
As we
know, the prefix of geotextile, geo, means earth and the ‘textile’ means
fabric. Therefore, according to the definition of ASTM 4439, the geotextile is
defined as follows:
"A
permeable geosynthetic comprised solely of textiles. Geotextiles are used with
foundation, soil, rock, earth, or any other geotechnical engineering-related
material as an integral part of human-made project, structure, or system."
The
ASAE (Society for Engineering in Agricultural, Food, and Biological Systems)
defines a geotextile as a "fabric or synthetic material placed between the
soil and a pipe, gabion, or retaining wall: to enhance water movement and retard
soil movement, and as a blanket to add reinforcement and separation." A
geotextile should consist of a stable network that retains its relative
structure during handling, placement, and long-term service. Other terms that
are used by the industry for similar materials and applications are geotextile
cloth, agricultural fabric, and geosynthetic.
2. THE TYPES OF GEOTEXTILE
In
general, the vast majority of geotextiles are made from polypropylene or
polyester formed into fabrics as follows:
- Woven monofilament
- Woven multifilament
- Woven slit-film monofilament
- Woven slit-film multifilament
- Nonwoven continuous filament
heat bonded
- Nonwoven continuous filament
needle-punched
- Nonwoven staple
needle-punched
- Nonwoven resin bonded
- Other woven and nonwoven combinations
- Knitted
- 3.
RAW MATERIAL OF GEOTEXTILE
The
four main polymer families most widely used as the raw material for geotextiles
are:
Polyester
Polyamide
Polypropylene
Polyethylene
The
oldest of these is polyethylene, which was discovered in 1931 in the research
laboratories of the ICI. Another group of polymers with a long production
history is the polyamide family, the first of which was discovered in 1935.The
next oldest of the four main polymer families relevant to geotextile manufacture
is polyester which was first announced in 1941.The most recent polymer family
relevant to geotextiles to be developed was polypropylene, which was discovered
in 1954. The comparative properties of these four polymer are shown in very
general items in Table 1.
Table 1
|
Polyester
|
Polyamide
|
Polypropylene
|
Polyethylene
|
Strength |
H
|
M
|
L
|
L
|
Elastic modulus |
H
|
M
|
L
|
L
|
Strain at failure |
M
|
M
|
H
|
H
|
Creep |
L
|
M
|
H
|
H
|
Unit weight |
H
|
M
|
L
|
L
|
Cost |
H
|
M
|
L
|
L
|
Resistance to: |
|
|
|
|
U.V. light stabilized |
H
|
M
|
H
|
H
|
unstabilized |
H
|
M
|
M
|
L
|
Alkalis |
L
|
H
|
H
|
H
|
Fungus, vermin |
M
|
M
|
M
|
H
|
Fuel |
M
|
M
|
L
|
L
|
Detergents |
H
|
H
|
H
|
H
|
4. THE BASIC PROPERTIES OF
GEOTEXTILE[1]
The
properties of polymer material are affected by its average molecular weight (MW
) and its statistical distribution. Increasing the average MW results in
increasing:
- tensile strength
- elongation
- impact strength
- stress crack resistance
- heat resistance
Narrowing the molecular weight distribution results in:
- increased impact strength
- decreased stress crack
resistance
- decreased processability
Increasing crystallinity results in:
- increasing stiffness or
hardness
- increasing heat resistance
- increasing tensile strength
- increasing modulus
- increasing chemical
resistance
- decreasing diffusive permeability
- decreasing elongation or
strain at failure
- decreasing flexibility
- decreasing impact strength
- decreasing stress crack
resistance
5. MARKET ACTIVITY
To say
that the market activity of geosynthetics in the geotechnical, transportation,
and environmental areas is strong is decidedly an understatement. To obtain an
insight into the vitality of geosynthetics, note the curves in the graphs in fig 3a and 3b. The curves in
Fig. 3a gives the estimated amount of geosynthetics used in North America over
the years(geopipe is not shown ), while the curve in Fig 3b gives the estimated
in-place expenditures of these products.
Used
in the calculations were the data for 1995 (note that the values are in
millions of square meters and millions of dollars ) [ 1 ]:
Geotextiles 500 Mm2 @ $ 0.9 / m2 = $ 450 MGeogrids 40 Mm2 @ $ 2.50 / m2 = $ 100 M
Geonets 50 Mm2 @ $ 2.00 / m2 = $ 100 M
Geomembranes 75 Mm2 @ $ 10.00 / m2 = $ 750 M
Geosynthetic clay linears 50 Mm2 @ $ 2.5 / m2 = $ 125 M
Geocomposites 25 Mm2 @ $ 5.00 / m2 = $ 125 M
Geo-others 5 Mm2 @ $ 4.00 / m2 = $ 20 M
Total ( 1995 ) $ 1670 M
6. THE BASIC FUNCTION OF GEOTEXTILE
Geotextiles
form one of the two largest groups of geosynthetics. Their rise in growth
during the past fifteen years has been nothing short of awesome. They are
indeed textiles in the traditional sense, but consist of synthetic fibers
rather than natural ones such as cotton, wool, or silk. Thus biodegradation is
not a problem. These synthetic fibers are made into a flexible, porous fabric
by standard weaving machinery or are matted together in a random, or nonwoven,
manner. Some are also knit. The major point is that they are porous to water
flow across their manufactured plane and also within their plane, but to a
widely varying degree. There are at least 80 specific applications area for
geotextiles that have been developed; however, the fabric always performs at
least one of five discrete functions:
1.
Separation
Geotextiles function to prevent mutual
mixing between 2 layers of soil having different particle sizes or different
properties. Table 2 shows the required properties for separation:
Table
2 The required properties for separation
|
Mechanical
|
Hydraulic
|
Long-term Performance
|
During installation
|
Impact resistance
Elongation at break
|
Apparent opening
size ( A.O.S.)
Thickness
|
UV resistance
|
During construction
|
Puncture resistance
Elongation at break
|
Apparent opening
size ( A.O.S.)
Thickness
|
Chemical stability
UV resistance
|
After completion of construction
|
Puncture resistance
Tear propagation resistance
Elongation at break
|
Apparent opening
size ( A.O.S.)
Thickness
|
Chemical stability
Resistance to decay
|
- Drainage
:
The function of drainage is to gather water, which is not required
functionally by the structure, such as rainwater or surplus water in the soil,
and discharge it.
Table 3. The required properties for
drainage:
|
Mechanical
|
Hydraulic
|
Long-term Performance
|
Permanent drainage function
|
Influence of normal overburden
pressure
|
Permeability
Thickness
Apparent opening
size (A.O.S.)
|
Chemical properties of water and soil
Chemical stability
Decay resistance
|
Temporary drainage function
|
Influence of normal overburden
pressure
|
Permeability
Thickness
Apparent opening
size (A.O.S.)
|
|
- Filtration :
Filtration involves the establishment of a stable interface
between the drain and the surrounding soil. In all soils water flow will induce
the movement of fine particles. Initially a portion of this fraction will be halted
at the filter interface; some will be halted within the filter itself while the
rest will pass into the drain. The geotextile provides an ideal interface for
the creation of a reverse filter in the soil adjacent to the geotextile. The
complex needle-punched structure of the geotextile provides for the retention
of fine particles without reducing the permeability requirement of the drain.
Table
4. The required properties for Filtration:
|
Mechanical filter stability |
Hydraulic filter stability |
Long-term performance |
Permanent filter function
|
A.O.S.
Thickness
|
Geotextile permeability
|
Chemical properties of water and
soil
Chemical stability
Decay resistance
|
Temporary filter function
|
A.O.S.
Thickness
|
Geotextile permeability
|
|
- Reinforcement
Due to their high soil fabric friction coefficient and high
tensile strength, heavy grades of geotextiles are used to reinforce earth structures
allowing the use of local fill material.
Table
5: The required properties for reinforcement:
|
Mechanical
|
Hydraulic
|
Long-term performance
|
Base failure
|
Shear strength of bonding system
|
Hydraulic boundary conditions
|
Chemical and decay resistance
|
Top failure
|
Tensile strength of geotextile
Geotextile/ soil friction
|
Hydraulic boundary conditions
|
Chemical and decay resistance
|
Slope failure
|
Tensile strength of geotextile
Geotextile/ soil friction
|
|
Creep of the geotextile/ soil
system
Chemical and decay resistance
|
- Protection:
Erosion of earth embankments by wave action, currents and repeated
drawdown is a constant problem requiring the use of non-erodable protection in
the form of rock beaching or mattress structures. Beneath these is placed a
layer of geotextile to prevent leaching of fine material. The geotextile is easily
placed, even under water.
Table
6:. The required properties for protection
|
Mechanical
|
Long-term performance
|
Tunnel construction
|
Burst pressure resistance
Puncture resistance
Abrasion resistance
|
Chemically stable: pH=2-13
Decay resistance
|
Landfill and reservoir
geomembrane construction
|
Puncture resistance
Burst pressure resistance
Friction coefficient
|
Chemically stable: pH=2-13
Decay resistance
|
Flat roof construction
|
Puncture resistance
|
Chemical compatibility
|
7. APPLICATIONS
Case ( I ) :
Wet soil conditions in animal feeding and
high-traffic live-stock handling areas cause problems for both animals and
producers, as well as the environment. Ruminating animals, such as beef, dairy,
and sheep, often concentrate at stream crossings, in paddock lanes, and in
feedlots and barnyards. In association with animal production, there will be
concentrated farm vehicular and equipment traffic. When the animal and/or
equipment traffic is excessively high, the vegetation is destroyed. During and
after rainy weather, the soil in these areas turns to mud, creating an
unhealthy environment for optimal livestock production, poor traction for farm
equipment, and potentially poor surface water quality. Once these areas dry,
they may provide rough and possibly hazardous footing for the animals.
After
the vegetation in these concentrated areas is destroyed, the soil is bare and
subject to erosion. In addition, once wet soil that has been trampled by
livestock dries, it has a greatly reduced infiltration rate, and thus a much
higher potential for producing runoff of soil and manure. Both of these
conditions are conducive to creating a water quality problem. However, all of
the conditions summarized above cause problems for producers as they try to
properly manage the many operations for a profitable livestock production
system.
The
use of geotextile fabric in these high-traffic livestock areas can
substantially reduce the occurrence of adverse conditions (see Figure 1). The
installation of geotextile fabric combined with gravel can help provide a
proper surface that animals, humans, vehicles, and equipment can travel on, and
can also provide an erosion control benefit.
The
purpose of this publication is to help producers, landowners, and agency and
industry personnel who work with producers and landowners, understand the
proper application, installation, and maintenance of geotextile fabric for
agricultural applications. This publication provides an overview of a
demonstration project (Using Geotextile Cloth in Livestock Operations to Reduce
Nutrient and Sediment Loading in the Olentangy Watershed) on the use of
geotextile fabric in high-traffic livestock areas. Some of the material
provided is based on cooperative agency-industry-producer experiences from
twelve project sites constructed in Morrow
County, Ohio, during 1994.
The
leading cause of pavement and roadway failure in the U.S. is
contamination of the aggregate base and the resulting loss in aggregate
strength. When aggregate is placed on a subgrade, the bottom layer becomes
contaminated with soil. Over time, traffic loading and vibration punches
pavement base aggregate into the soil and causes silt and clay to migrate
upward. On wet sites, construction traffic causes pumping of weak subgrade
soils into overlying aggregate. All of these conditions decrease the effective
aggregate thickness destroying the road support and reducing roadway
performance and life.
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