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Design Parameters

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... analysis of samples, hydrogeological data as well as data on seismicity etc. ... published papers, geological maps, seismicity maps, other geological or ... – PowerPoint PPT presentation

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Title: Design Parameters


1
Design Parameters
2
Classification in Design Stage and Assessment of
Design Parameter
  • All the efforts of the engineering geological
    investigation steps already performed in previous
    stages of the project are the basis for the
    establishment of geological models and later on
    to the assesment of design criteria.
  • The establishment of the geological model has the
    scope to define where and which geotechnical rock
    mass properties to be used as design parameters
    to be applied for the coming design steps.
  • The values obtained by site and laboratory
    investigations represent characteristics for the
    special point where they were taken from.

3
  • The rock mass is affected by a number of impacts
    converting the physical and rock mechanical
    properties to the worst. These may be for
    example
  • Weathering
  • Volcanic or postvolcanic processes
  • Tectonic processes
  • Influences of pore- and groundwater
  • Slope instabilities
  • After collecting all data by desk studies, field
    survey, subsurface investigations, laboratory and
    in situ testing, the geological model and
    geotechnical rock mass properties have to be
    established.

4
  • The empirical methods help to establish
    geological models by the use of statistical and
    probabilistic analysis of the collected data
    (structural data, data on mechanical properties
    and mineralogical analysis of samples,
    hydrogeological data as well as data on
    seismicity etc.).
  • After the collection of the data is finished, an
    evaluation of the different impacts of these
    parameters (as mechanical behavior of
    discontiniuities, pore water pressure, activity
    of fault zones, distribution of swelling
    clayminerals, tectonic stress fields etc.) on the
    concerned project has to be performed.
  • The empirical approach with the use of matrices
    for the introduction of the relative importance
    of the individual parameter sets requires an
    appropriate geological model and further on leads
    to the classification of the design stage.

5
How to achieve this geological model
  • The first step is the evaluation of all
    available investigation results being elaborated
    in the previous working steps, such as
  • Desk study reports concerning published papers,
    geological maps, seismicity maps, other
    geological or geotechnical project reports
  • Analysis of aerial photos
  • Results of detailed geological mapping
  • Results of subsurface investigations as trial
    pits and trenches, drill holes, adits etc.
  • Results of geophysical studies
  • Results of insitu tests
  • Hydrogeological studies
  • Results of laboratory tests on physical
    properties and mechanical parameter of soil and
    rock samples
  • Results of laboratory tests concerning minerology
    and petrography of soil and rock samples
  • Results on slope monitoring by survey

6
  • Next step is the preparation of the
  • Geological longitudinal sections and
  • Geological cross sections.
  • Based on the results of the detailed geological
    mapping, the subsurface investigation results and
    the knowledge on the geological situation.
  • The products of this step must give a clear
    information on, which different rock (soil) types
    occur in the project, their physical properties
    and mechanical parameters and locations.

7
  • Assesment of Design Parameters and
    Classification
  • The next step will be converting this knowledge
    into geotechnical terms applicable for the
    assesment of design parameters.
  • The emphasis lies on gaining clear understanding
    concerning the geomechanical conditions before
    the design object is implemented,
  • -changes that may arise during the excavation and
    construction and
  • -the state after the completion of the project

8
  • Since geological conditions vary from site to
    site an examination of their impacts on the
    project must be done.
  • The most advanced way to do this is to set up a
    matrix which highlights the individual geological
    parameters such as
  • distribution of discontinuities,
  • shape and position of keyblocks,
  • mechanical behavior along discontinuities,
  • ground or pore water conditions,
  • tectonic stresses,
  • expected deterioration of rock mass properties
    during excavationdue to minerological conditions
    like swelling etc.

9
  • For each project the influence of each geology
    related parameter must be rated indivudually as
    it depends on the size of the opening, the
    construction method, the orientation of the
    opening towards discontinuities.
  • After the preparation of this matrix the
    geotechnical longitudinal profile has to be
    prepared.
  • Parts of the tunnel with similar geotechnical
    behavior are now recognizable in this
    longitudinal profile. Change points and
    classification for the assesment of design
    parameters at the design stage are more clear at
    that point.

10
  • Selection of Design Zones (Longitudinal
    Section)
  • By the selection of design zones, the tunnel is
    divided, along its alignment, in longitudinal
    sections. Within one zone a similar behavior of
    the ground and the structure is expected. In the
    evaluatiion of design zones following steps are
    followed
  • - estimate of the size of the influence zone of
    construction
  • - evaluation of the dominating construction
    specific parameters (required information!)
  • - selection of the design zones

11
  • In relation to the surface and sub-ground
    condition and with respect to the structural
    layout required information
  • topography and overburden
  • surface structures
  • surface hydrological conditions
  • stratification
  • classification of soil layers (classification
    parameters, density, stiffness)
  • assessment of the groundwater condition (GW flow,
    water pressure distribution, aquifer system)
  • Tunnel geometry
  • Conditions at the portal zones of the tunnel
  • Zones of enlargement of the standard tunnel
    section
  • Cross passages
  • Connection with ventilation shafts, tunnels or
    similar structural constraints

12
  • Soil Parameters
  • Using the results of field and laboratory
    investigations, soil properties and soil
    parameters are evaluated according to the defined
    design zones and stratification system. This
    includes direct use of factual data and the
    direct assesment on the basis of correlation to
    other soil parameters. A sound local experience
    of the ground and engineering judgement may be
    needed for the verification of the data.

13
  • Design sections and Design parameters
  • The number of design sections will be defined on
    the basis of changes of the surface and subground
    condition and with respect to the structural
    layout.
  • Design parameters are design specific soil
    parameters and are determined for the particular
    design section according to the input
    requirements of the calculation method. They
    comprise the following information
  • thickness of the individual layer
  • unit weight
  • Water table and water pressure distribution
  • Modulus of the ground
  • Poissons ratio
  • Shear parameters (friction, cohesion)
  • Coefficient of the earth pressure at rest
  • Subgrade reaction
  • Design section represents an average section, so
    there is no need to assume the lowest value for
    all design data. In general the average soil
    parameters within the respectve design zone and
    the average layering system will be adopted for
    the design.

14
  • For the definition of different load cases short
    and long term conditions as well as a possible
    range of design parameters must be considered.
    Such as drained or undrained conditions, low and
    high groundwater table.
  • For the determination of the shear parameters,
    it will be necessary to consider both, short term
    and long term ground behavior with respect to the
    time of consolidation in relation to stress
    changes.
  • The permanent design should be based on the less
    favourable condition. As in most of the soils
    fully undrained conditions will be for a very
    short period only. Undrained shear strength might
    be used for the estimate of the stand up time of
    the unprotected soil face during excavation,
    while the actual temporary support system will be
    determined also by the less favourable condition

15
  • Design methods and engineering classification of
    rock masses for the design of tunnel supports
  • Basically there are four different groups of
    design methods
  • Empirical
  • Observational
  • Analytical
  • numerical

16
  • Rock classifications
  • Rock classifications were developed to provide
    the design aids forming only a part of the tunnel
    engineers bag of tools.
  • Describing the rock through which a tunnel has
    an importance to choose the support system and
    the excavation method. Different classification
    system are used commonly in practical
    applications.
  • In general there are 3 applications
  • Geologic, geotechnical descriptions where one or
    several parameters are standardized
  • Quantitative descriptions of significant
    parameters of the rock mass which can directly or
    indirectly be used as design support
  • Description of the qualitative behavior of the
    rock mass during and after excavation, including
    the influence of the support
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