Stability analysis of a high excavated slope.
Hai-Jia, Wen ; Jia-Lan, Zhang ; Yong-Xin, Zhang 等
This work aimed to study on stability-assessment way of a high
excavated-slope. A stable slope was the key to insure the security of
building site adjacent to the high slope, which frequently encountered
in town construction at mountain areas by terrain limit. Some crucial
problems were summarized for stability assessment of an excavated high
slope based on several typical engineering cases in Chongqing. A
synthetical-analysis way was explored to assess stability of high slope
from its natural geological conditions and its man-destroyed degree,
engineering environment, potential failure pattern of a high slope,
calculation parameters and analysis methods. As a result, it is
indicated that the conclusion of stability assessment can be determined
according to the aspects abovementioned, and the stability assessment is
one of the fundamental data to insure the safety of the related
construction, site and buildings.
Key words: high slope; geological environment;
synthetical-analysis; stability assessment
INTRODUCTION
Mountains and highlands cover about one quarter of the world's
landmass and are home to about 10% of the world's population.
Building development of mountain areas, has received international
attention, and the 2002-year was the United Nations International Year
of the Mountains (U.N. IYM 2002).
In China, mountains and highlands cover 69% of the country's
land surface and are home to 56% of the Chinese population. So the
'All-out Development Strategy for Western Regions', brought
into effect by the central government of P.R. China in 2000, is also a
great movement towards developing mountainous areas in western China.
Increased development of mountain areas has appeared specific
engineering problems associated with hill-side construction. Typically,
the safety problem of building sites adjacent to high excavated slopes,
widely encountered in west China, is an issue.
This problem is widespread in Chongqing, a city representative of
mountainous regions in west China. To ensure the safety of buildings and
construction sites, an assessment of stability of the excavated slope is
required to determine whether advance reinforcement is necessary.
Unstable excavated slopes may lead to landslides, such as the incident
at Wulong, Chongqing, (2001), shown in Figure 1, where a 9 storey
building collapsed and 86 people were killed/injured.
Therefore, stability assessment is very important for building
sites adjacent to excavated high slopes. However, it is difficult to
obtain accurate assessments because of the many complicated factors
determining the in-situ slope stability. Crucial factors include:
natural geological conditions, degree of anthropogenic disturbance,
engineering environment, potential failure pattern, calculation
parameters and analysis methods.
The natural geological condition is essential in determining the
stability of high excavated slopes. The main factors of influence are:
the properties of rock and soil mass, stratum attitude, associated dip
situation of the stratum and excavated slope, geological structure (such
as the growth degree of fissures, faults and groundwater regime).
Building site excavation can also disturb geological conditions with
deletesions effects.
Combinations of weak rock and/or soil, widely encountered in slope
engineering, usually leads to depressed slope stability. In Chongqing,
strata including incompact soil, sandstone, and mudstone are widespread.
In the Wulong landslide example (Figure 1.), the main strata are
[Q.sup.4] soil, [T.sub.3xj] sandstone and mudstone weak interbed. The
combined strata of [Q.sup.4] soil, [J.sub.2][S.sup.2] sandstone and
mudstone is typical at many building sites in the Chongqing urban
district, as shown in Figure 2.
[FIGURES 1-2 OMITTED]
The slope may be stable state if the stratum tilt direction is
opposite to the excavated slope's dip. However, many excavated
slopes are unstable because of the identical tilt direction of the
stratum and slope, following a disadvantageous excavation, without
retaining structures, as shown in Figure 2. and Figure 3. For instance,
during 319 state railway and building construction, at the site of the
Wulong landslide, the foot of the slope has been badly excavated since
1989.
[FIGURE 3 OMITTED]
Generally, the integrity of natural rock and soil is destroyed and
the mechanics properties are weakened by growing geological structures
such as fissures. The Wulong landslide had a slight tilt angle stratum,
however the rock mass was split into fractional clump layers mainly by
two joint set parallel and vertical to slope surface respectively. This
rock slope was unstable because the fractional clump was split by
fissures.
According to surveys, over 90% of high slope landslides are
attributed to groundwater. Groundwater may increase the unit weight and
decrease the mechanical strength of the rock-soil mass, causes static
and dynamic water pressure, scours or corrodes the slope foot and
results in flotage of rock-soil. During the rainy season, slope
stability is greatly reduced due to the groundwater, and additionally,
soil moisture and surface water. For instance, the Wulong landslide was
preceded by a heavy rainfall.
ENGINEERING ENVIRONMENT
Engineering environment refers to construction-engineering
movements at the building site adjacent to the high excavated slope.
Generally, natural slopes are stable, but slopes become unstable once
the equilibrium condition has been disturbed by anthropogenic
engineering movement. The Wulong landslide is a typical example.
Other engineering factors of slope stability include unsuitable
landfill materials, construction materials, deposited at the top of the
slope, engineering blasts construction, traffic vibration and seepage
from an engineering service pipe or drainpipe. Such factors are
typically observed in Chongqing city, as shown in Figure 4. and Figure
5.: a drainpipe crossing the upper side of an high excavated slope and
heavy traffic at the top of an high excavated slope respectively.
[FIGURES 4-5 OMITTED]
STABILITY ASSESSMENT
A stability assessment will provide important data for the design
and construction for slope retaining structures. An accurate and precise
assessment of the excavated slope stability is essential to ensure the
safety of the site and buildings. In Chongqing, it is compulsory to
assess the following classes of slope prior to construction:
classification slope and its height over 25 m, classification and
H[greater than or equal to]15m, classification and H[greater than or
equal to]8m.
An accurate assessment of a high excavated slope may be based on
the clear investigation of the afore mentioned natural geological
conditions, and the degree of anthropogenic/engineering disturbance to
the building site. To obtain an exact assessment conclusion, the
following aspects also need to be thoroughly studied, in terms of the
related geological survey datum and technical standard. Potential
failure pattern
The potential failure pattern of high excavated slopes may be
determined during the stability assessment.
The potential failure pattern of the case shown in Figure 3 may be
linear shear failure with a single slip surface. Rotary failure with an
are slip surface can occur in homogeneous soil slopes, landfill slopes
and rock slopes with a prosperous fissure. Shear failure with
multi-replicate slip surfaces may occur in rock masses with identical
dips multi-discontinuity or landfill on the replicate surface of
bedrock. Excavated slopes with steep gradients and ground fissuration at
the top of slope are prone to toppling collapse. Fractionary collapse
with complex slip surface may occur at slopes with slight dip angle
Figure 5. The heavily trafficked road at the top of a high excavated
slope stratum, layer on layer with crashed part by joint set, as
observed at the Wulong landslide, Figure 6.
[FIGURE 6 OMITTED]
Assessment method
The potential failure pattern of high-excavated slopes is an
important criterion in the selection of stability assessment method.
The ordinary method is appropriate for linear shear failure with
single slip surface. Integrative C value method is usually adopted for
rotary failure with are slip surface. The transfer coefficient method
may be suitable for shear failure with multi-replicate slip surfaces.
The SARMA method is generally used for arbitrary boundary of slip
surface and the rock mass separated by distinct discontinuity. Graphic
methods include stereographic projection and sphere projection method.
The former is suitable for rock masses with less distinct discontinuity
and the latter is used for failure controlled by a large dimension
wedge. More complex failures need to be analyzed by numeric methods such
as FEM (finite element method).
It is difficult to obtain a convincing assessment conclusion using
a single assessment method, therefore the local technical standard in
Chongqing recommends that: "... engineering geological analogy and
limit equilibrium method should be comprehensively used.... Numeric
method ought to be combined to analyze the stability for the slope with
complex deformation and failure mechanism."
Calculation parameter
An accurate calculation parameter for rock and soil mass, specific
to the site, must to be used or the stability assessment will be
inaccurate, regardless of the good computational method used.
The calculation parameter of rock-soil mass can be determined from
the geotechnical investigation report of the specific slope plus the
related technical standard. The parameters described by the site
investigation report may not accurately represent the rock-soil mass
in-situ because the experiment conditions to test these parameters are
often simplified. Therefore Technical Standards recommend that the final
calculation parameter should additionally consider factors such as
service condition of high slope with the length of building service. In
the absence of experimental values, the related technical standard may
be used to offer these calculation parameters.
Engineering significance
The conclusions of stability assessment are important to help
ensure slope stability and therefore building safety. Moreover, it is an
important factor in determining the need for structures and the methods
of excavation.
The excavation of natural rock-soil is disadvantageous to the
stability of high slopes due to the intrinsic destruction of the
equilibrium and the mechanical properties of rock mass, which becomes
weakened by weathering over time. Retaining structures should be used
when the stability assessment shows that the excavation results in slope
failure. Specific measures are necessary to deal with the sensitive
factors forward to reduce high slope stability. The disjunction and
topdown construction method ought to be used in slope excavation
construction if it is shown that a large degree of distortion would
occur if a "one-off" excavation procedure was adopted. Some
other aspects, including the use of engineering blast methods and the
quantity of explosive used in excavation construction, may be decided
according to the stability dynamic assessment.
CONCLUSIONS
1) Accurate stability assessment of high excavated slopes is
fundamental to ensure the safety of the related excavation construction
site and buildings.
2) The stability assessment is influenced by several crucial
factors: the natural geological conditions and anthropogenic disturbance
of these conditions, the engineering environment, potential slope
failure pattern, assessment calculation parameters and analysis method.
3) The conclusion of the stability assessment helps estimate the
safety of building sites adjacent to high slope and also provides
important data used to determine the strategy for excavated
slope-retaining structures.
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WEN HAI-JIA, ZHANG JIA-LAN, ZHANG YONG-XIN
Faculty of Civil Engineering, Chongqing University, Chongqing
400045, P.R. China
