Instruc. MEPADS
-
Upload
anderzon-mora -
Category
Documents
-
view
244 -
download
0
description
Transcript of Instruc. MEPADS
-
OVERVIEW OF THE SOUTH AFRICAN MECHANISTIC PAVEMENT
DESIGN METHOD
Paper modified form the preprint presented at the 1996 annual meeting of the
Transportation Research Board
H L Theyse, Project Leader.
Transportek, CSIR
P O Box 395 Telephone: +27 12 841-2911
Pretoria Telefax: +27 12 841-3232
0001
South Africa
Abstract
This paper presents an historical overview of the development of the South African Mechanistic
Pavement Design Method as well as an overview of the method as it is used currently. The
development of the method is briefly traced since the early 1970's. The material
characterization, structural analysis and pavement bearing capacity prediction of the current
method are discussed. Suggested ranges of stiffness values are provided for asphalt, granular,
cemented, selected and sub-grade material. The modes of failure for these material types include
the fatigue of asphalt material, permanent deformation of granular material, crushing and
effective fatigue of lightly cemented material and permanent deformation of selected and sub-
grade material. The critical parameters and transfer functions for these material types and modes
of failure are discussed and included in the process for estimating the pavement bearing capacity.
-
H L Theyse 1
INTRODUCTION
Pavement design methods provide the scientific tools for estimating the bearing capacity of
pavements. It is not the purpose of pavement design methods to do a full simulation of real life
pavement behaviour and performance but rather to provide a method for the unbiased estimation
of the bearing capacity of alternative design options with the aim of selecting the design that will
provide the required bearing capacity in the most economical way.
The South African Mechanistic Design Method (SAMDM) and the development of certain
components of the method have been published widely over the last few decades. These
previous publications discussed the holistic approach to pavement design (including material and
pavement behaviour, design traffic, desired service level etc.) as well as the mechanistic-
empirical design procedure. The purpose of this document is to give an overview of the current
mechanistic design procedure and not the complete pavement design approach. The paper
discusses the historical development of the method as well as the procedure as it is used
currently, including components of the procedure that have been developed recently.
Figure 1 illustrates a basic mechanistic-empirical design procedure. The process starts off with
the load and material characterization. The standard design load for South Africa is a 40 kN
dual wheel load (based on the legal axle load of 80 kN allowed on public roads) at 350 mm
spacing between centres and a uniform contact pressure of 520 kPa.
The material characterization includes layer thickness and elastic material properties for each
layer in the pavement structure under consideration. The structural analysis will usually be a
-
H L Theyse 2
Pavement Bearing CapacityEstimate
Structural Analysis Model:Pavement Response
FF & ,,
Pavement Performance Model:Transfer Function
Adequate ?No
Final Pavement Design
Yes
linear elastic, static analysis of the multi layer system from which the pavement response to the
loading condition is calculated in terms of stresses (F) and strains (,) at critical positions in the
pavement structure. These critical positions are determined by the material type used in each
layer of the pavement structure.
FIGURE 1: FLOW DIAGRAM FOR A MECHANISTIC-EMPIRICAL DESIGN
PROCEDURE
The critical pavement response parameters serve as input to the transfer functions applicable to
particular material types and modes of failure. The transfer functions relate the stress/strain
condition to the number of loads that can be sustained at that stress/strain level before a certain
-
H L Theyse 3
terminal condition for a particular mode of distress is reached.
This paper focuses on the material characterization, structural analysis and transfer function
components of the procedure currently used in South Africa.
HISTORICAL DEVELOPMENT OF THE SOUTH AFRICAN MECHANISTIC DESIGN
METHOD
The first simplified mechanistic design procedure for South Africa was developed by Van
Vuuren, Otte and Paterson (1) during 1974. The first comprehensive publication on mechanistic
pavement design in South Africa is contained in a paper at the 1977 International Conference
on the Structural Design of Asphalt Pavements by Walker, Paterson, Freeme and Marais (2).
At that stage no values for the characterization of the pavement materials were provided and
it was suggested that material characterization should be done by laboratory and field testing for
each design. Transfer functions were provided for the fatigue life of thin asphalt surfacing layers
as a function of the maximum horizontal tensile strain at the bottom of the asphalt layer after
Freeme and Marais (3). No transfer functions were provided for thick asphalt base layers at that
time. A fatigue transfer function developed by Otte (4,5,6) for the crack initiation of cemented
material based on the maximum tensile strain at the bottom of the layer, was included. The only
criteria provided for granular base layers was that the working stresses should be limited to 70%
of the static shear strength or that the safe working stresses should be determined from repeated
load triaxial tests. The same criteria were suggested for the selected layers and subgrade
material.
-
H L Theyse 4
In addition to providing transfer functions for various material types Paterson and Maree (7) in
1978 suggested elastic properties for different road building materials in South Africa. The
fatigue criteria for thin asphalt layers remained the same as those given by Walker et al (2) but
Paterson and Maree (7) included transfer functions for thick asphalt base layers. The fatigue
criteria for cemented material provided by Walker et al (2) were also used by Paterson and
Maree (7). The concept of the safety factor for limiting the permanent deformation of granular
material was introduced based on work done by Maree (8). The safety factor is calculated from
the major and minor principle stresses at the midpoint of the granular layer as an indication of
the ratio of the material shear strength to the working shear stress. Criteria developed by
Paterson (9) for limiting the permanent deformation of the selected and subgrade material as a
function of the vertical compressive strain at the top of these layers were included.
During 1981, Maree and Freeme (10) and in 1983, Freeme (11) reported on the use of the South
African Mechanistic Design Method for new pavement design and rehabilitation design. At that
stage the method had been refined and tested extensively mainly through accelerated testing of
pavements with the fleet of Heavy Vehicle Simulators (HVS's) in South Africa. The transfer
functions for asphalt material were extended to include fatigue transfer functions for thick
asphalt base layers as a function of the maximum horizontal tensile strain at the bottom of the
layer for a range of stiffness values (1000 to 8000 MPa) after Freeme and Strauss (12). The
criteria for predicting the behaviour of cemented and granular material remained the same as
listed previously by Paterson and Maree (7). The criteria for limiting the permanent deformation
of the selected and subgrade material were based on the criteria set by Paterson (9) and work
done at the U. S. Army Engineers Waterways Experiment Station (WES) by Brabston, Barker
and Harvey (13).
-
H L Theyse 5
The South African Mechanistic Design Method was updated in 1995 by Theyse (14,15) for the
purpose of revising the 1985 TRH4 catalogue of pavement designs (16). Transfer functions
were modified to include the approximate performance reliability required for the different
service levels attached to the different road categories in South Africa as given in Table 1.
TABLE 1: Road Categories and Approximate Design Reliabilities used in South Africa
Road Category DescriptionApproximate design reliability
(%)A Interurban freeways and major
interurban roads95
B Interurban collectors and majorrural roads
90
C Rural roads 80
D Lightly trafficked rural roads 50
The concept of crushing in lightly cemented layers as a function of the vertical stress at the top
of the cemented layers was introduced based on results form accelerated pavement testing (using
a HVS) by De Beer (17). The original fatigue criteria for cemented layers developed by Otte
(4,5,6) were also replaced by the effective fatigue criteria developed by De Beer (17). The
design method was calibrated extensively against the experience of road engineers from
different road authorities in South Africa in the process of revising the TRH4 pavement design
catalogue (16).
Although the development of the various components of the South African Mechanistic Design
Method and more specifically the transfer functions included in the method is an ongoing
process, the formal updating and comprehensive reporting of the method seems to be linked to
the revision of the TRH4 Pavement Design Catalogue. The method as reported by Walker et al
(2) in 1977 and Paterson and Maree (7) in 1978 was used in the development of the pavement
-
H L Theyse 6
design catalogue for TRH4 (1978). The method as reported by Maree and Freeme (10) in 1981
was used to revise the pavement design catalogue for TRH4 (1985) and the method updated in
1995 by Theyse was used for the revision of the catalogue for Draft TRH4 (1995).
MATERIAL CHARACTERIZATION FOR THE CURRENT SAMDM.
The standard road building materials for South Africa as discussed in TRH14 (1985): Guidelines
for Road Construction Materials (18) are listed in Table 2 with their material codes. The
suggested stiffness values contained in this section should only serve as a guideline to be used
in the absence of laboratory or field measured values or to test values obtained form laboratory
testing. It is strongly recommended that materials should be tested in the laboratory for
individual designs.
Asphalt Material
Freeme (11) suggested the elastic moduli for asphalt material listed in Table 3. Jordaan (19)
suggested the values listed in Table 4 based on elastic moduli back-calculated from Multi-depth
Deflectometer (MDD) deflection measurements. These values are considerably less than the
values listed by Freeme due to the fact that the second set of values was obtained from back-
calculation of field deflections. There is still some uncertainty over which approach to use
(laboratory versus field values) and the values listed by Freeme are still preferred until the issue
is resolved. The value used for the Poison's Ratio of asphalt material is assumed to be 0.44 or
as measured in the laboratory.
Cemented Material
-
H L Theyse 7
GM 'p2,000mm % p0,425mm % p0,075mm
100
Table 5 contains the suggested elastic moduli values for cemented material in different phases
of material behaviour after De Beer (20). The value used for the Poison's Ratio of cemented
material is 0.35.
TABLE 2: South African Road-building Materials with their Material CodesSymbol Code Material Abbreviated specification
G1 Graded crushedstone
Dense-graded, unweathered crushed stone; Max size37,5 mm; 88% apparent density; PI < 4,0 (min 6 tests)
G2 Graded crushedstone
Dense-graded crushed stone; Max size 37,5 mm; 100 -102 % mod. AASHTO or 85% bulk density; PI < 6,0(min 6 tests)
G3 Graded crushedstone
Dense-graded crushed stone and soil binder; max size37,5 mm; 98 - 100% mod. AASHTO; PI < 6
G4 Natural Gravel CBR 80; max size 53 mm; 98 - 100 mod. AASHTO;PI < 6; Swell 0,2 @ 100 % mod. AASHTO
G5 Natural Gravel CBR 45; max size 63 mm or b of layer thickness;density as prescribed for layer of usage; PI < 10; Swell0,5 @ 100 % mod. AASHTO
G6 Natural Gravel CBR 25; max size 63 mm or b of layer thickness;density as prescribed for layer of usage; PI < 12 or2(GM)+10; Swell 1,0 @ 100 % mod. AASHTO
G7 Gravel-soil CBR 15; max size b of layer thickness; density asprescribed for layer of usage; PI < 12 or 2(GM)+10;Swell 1,5 @ 100 % mod. AASHTO
G8 Gravel-soil CBR 10 at in-situ density; max size b of layerthickness; density as prescribed for layer of usage; PI