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GUIDE TO PAVEMENT TECHNOLOGY Part 6: Unsealed Pavements

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Page 1: P06-09 Unsealed Pavements

GUIDE TO PAVEMENT TECHNOLOGY

Part 6: Unsealed Pavements

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Guide to Pavement Technology Part 6: Unsealed Pavements

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Guide to Pavement Technology Part 6: Unsealed Pavements

Summary

Part 6 of the Guide to Pavement Technology addresses unsealed pavements including operational demands of unsealed road surfaces, pavement configurations, floodways, cuts, fills and mine haul roads, the identification of suitable pavement materials including commercially produced products and natural gravel sources, improvement of unsealed road pavement materials using modified stabilised materials, pavement design, including determination of required pavement thickness over the subgrade, drainage and erosion protection, and environmental considerations and performance expectation, including surface condition assessment. It is based on material contained in the ARRB Unsealed Roads Manual together with technical information contained in other relevant reports and documents.

Keywords

unsealed roads, unsealed road surfacings, pavement design, pavement materials, pavement performance, stabilisation, surface condition, pavement maintenance, pavement rehabilitation, life cycle costing, evaluation/assessment First Published September 2009 © Austroads Inc. 2009 This work is copyright. Apart from any use as permitted under the Copyright Act 1968, no part may be reproduced by any process without the prior written permission of Austroads. ISBN 978-1-921551-52-9 Austroads Project No. TP1565 Austroads Publication No. AGPT06/09 Project Manager

Chris Mathias Prepared by

Bob Andrews Published by Austroads Incorporated Level 9, Robell House 287 Elizabeth Street Sydney NSW 2000 Australia Phone: +61 2 9264 7088 Fax: +61 2 9264 1657 Email: [email protected] www.austroads.com.au This Guide is produced by Austroads as a general guide. Its application is discretionary. Road authorities may vary their practice according to local circumstances and policies. Austroads believes this publication to be correct at the time of printing and does not accept responsibility for any consequences arising from the use of information herein. Readers should rely on their own skill and judgement to apply information to particular issues.

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Guide to Pavement Technology Part 6: Unsealed Pavements

Sydney 2009

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Austroads profile

Austroads purpose is to contribute to improved Australian and New Zealand transport outcomes by:

providing expert advice to SCOT and ATC on road and road transport issues

facilitating collaboration between road agencies

promoting harmonisation, consistency and uniformity in road and related operations

undertaking strategic research on behalf of road agencies and communicating outcomes

promoting improved and consistent practice by road agencies.

Austroads membership

Austroads membership comprises the six state and two territory road transport and traffic authorities, the Commonwealth Department of Infrastructure, Transport, Regional Development and Local Government in Australia, the Australian Local Government Association, and New Zealand Transport Agency. It is governed by a council consisting of the chief executive officer (or an alternative senior executive officer) of each of its 11 member organisations:

Roads and Traffic Authority New South Wales

Roads Corporation Victoria

Department of Transport and Main Roads Queensland

Main Roads Western Australia

Department for Transport, Energy and Infrastructure South Australia

Department of Infrastructure, Energy and Resources Tasmania

Department of Planning and Infrastructure Northern Territory

Department of Territory and Municipal Services Australian Capital Territory

Department of Infrastructure, Transport, Regional Development and Local Government

Australian Local Government Association

New Zealand Transport Agency. The success of Austroads is derived from the collaboration of member organisations and others in the road industry. It aims to be the Australasian leader in providing high quality information, advice and fostering research in the road sector.

ACKNOWLEDGEMENT

The author acknowledges the significant compilation and editing of Chapter 5 Pavement Material Sources by William G Harvey (Department of Primary Resources Sth Aust).

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CONTENTS

1 INTRODUCTION ............................................................................................................ 1 1 Scope of Guide to Pavement Technology Part 6............................................................ 1

1.2 Guide to Pavement Technology ..................................................................................... 2 1.3 Unsealed Road Network Operation ................................................................................ 3 2 TYPES OF UNSEALED ROADS ................................................................................... 5 2.1 Pavement Configurations and Classifications ................................................................ 5 2.2 Selection of Pavement Type........................................................................................... 8 3 PAVEMENT MATERIALS............................................................................................ 10 3.1 Basic Pavement Material Principles for Unsealed Roads............................................. 10

3.1.1 Stability ........................................................................................................... 10 3.1.2 Resistance to Wear ........................................................................................ 12 3.1.3 Impermeability ................................................................................................ 12 3.1.4 Workability and Compaction ........................................................................... 13

3.2 Unbound Granular Specifications ................................................................................. 14 3.2.1 Maximum Size and Particle Size Distribution ................................................. 14 3.2.2 Base and Subbase ......................................................................................... 18

4 PAVEMENT THICKNESS............................................................................................ 19 4.1 Thickness Design Methodology.................................................................................... 19

4.1.1 Design Traffic.................................................................................................. 20 4.1.2 Thickness Design ........................................................................................... 20

5 PAVEMENT MATERIAL SOURCES ........................................................................... 22 5.1 Borrow Pit Geological Sources ..................................................................................... 22

5.1.1 Residual Deposits........................................................................................... 22 5.1.2 Colluvial Deposits ........................................................................................... 22 5.1.3 Alluvial Deposits ............................................................................................. 23 5.1.4 Concretionary Deposits .................................................................................. 23 5.1.5 Volcanic Deposits ........................................................................................... 23

5.2 Winning of Local Materials from Borrow Pits ................................................................ 23 5.2.1 Overview of Regulations................................................................................. 23 5.2.2 Pit Operation and Rehabilitation ..................................................................... 25

5.3 Processing Material from Borrow Pits........................................................................... 28 5.3.1 Processing on the Road Bed .......................................................................... 29 5.3.2 Mobile Plant Crushing..................................................................................... 30

6 STABILISATION OF UNSEALED ROADS ................................................................. 35 6.1 Types of Stabilised Materials........................................................................................ 35 6.2 Application of Stabilisation............................................................................................ 36 6.3 Granular Stabilisation by Blending Materials ................................................................ 36

6.3.1 Granular Mix Design ....................................................................................... 36 6.4 Stabilisation Using Chemical Binders ........................................................................... 38

6.4.1 Types of Chemical Stabilisation Binders ........................................................ 38 6.4.2 Applications .................................................................................................... 41 6.4.3 Product Selection and Mix Design.................................................................. 42

6.5 Stabilisation with Lime .................................................................................................. 43 6.6 Stabilisation with Cementitious Binders........................................................................ 43 6.7 Stabilisation with Powder Binders................................................................................. 43

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6.8 Methods of Applying Stabilisation Binders in the Field ................................................. 44 6.8.1 Powder Binders .............................................................................................. 44 6.8.2 Liquid Binders ................................................................................................. 44 6.8.3 Methods of Mixing........................................................................................... 45

6.9 Logistical Selection of Stabilisation Binders for Construction ....................................... 46 6.10 Technical Evaluation of Stabilisation Binder Performance ........................................... 46

6.10.1 Laboratory Evaluations ................................................................................... 46 6.10.2 Field Trials ...................................................................................................... 47

7 UNSEALED SURFACE WEARING CHARACTERISTICS.......................................... 48 7.1 Introduction................................................................................................................... 48 7.2 Types of Surface Wear ................................................................................................. 48

7.2.1 Loss of Fine Material (Dust)............................................................................ 48 7.2.2 Loose Gravel .................................................................................................. 52 7.2.3 Corrugations ................................................................................................... 53 7.2.4 Potholes.......................................................................................................... 55 7.2.5 Dry Rutting in Wheelpaths .............................................................................. 56 7.2.6 Surface Gouging............................................................................................. 56 7.2.7 Surface Scour ................................................................................................. 57 7.2.8 Ice Formation on Surface ............................................................................... 58

8 UNSEALED ROAD SURFACE MANAGEMENT......................................................... 60 8.1 Introduction................................................................................................................... 60 8.2 Surface Maintenance.................................................................................................... 60

8.2.1 Patrol Grading................................................................................................. 60 8.2.2 Reshaping and Shallow Stabilisation.............................................................. 62

8.3 Resheeting (Wearing Course Replacement) ................................................................ 63 8.3.1 Measuring and Estimating Gravel Loss .......................................................... 63 8.3.2 Predicting Gravel Loss.................................................................................... 64

8.4 Unsealed Road Condition Monitoring ........................................................................... 66 8.5 Visual Pavement Condition Rating Systems ................................................................ 67

8.5.1 South Africa .................................................................................................... 67 8.5.2 USA ................................................................................................................ 68

8.6 Quantitative Pavement Condition Rating...................................................................... 73 9 COST–BENEFIT CONSIDERATIONS......................................................................... 75 9.1 Concept ........................................................................................................................ 75 9.2 Life Cycle Analyses for Selection of Wearing Course and Associated

Maintenance Management Strategies .......................................................................... 75 9.2.1 Introduction ..................................................................................................... 75 9.2.2 Life Cycle Cost Analyses ................................................................................ 76 9.2.3 Grading Intervention Frequency and Sheeting Life ........................................ 78

REFERENCES ...................................................................................................................... 79

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TABLES

Table 1.1: References to unsealed pavement technology in the Austroads Guide to Pavement Technology and ARRB Unsealed Roads Manual............................ 2

Table 1.2: Key websites pertinent to unsealed road technology ....................................... 2 Table 2.1: Unsealed road classification ............................................................................. 6 Table 2.2: Indicative pavement type selection................................................................... 9 Table 3.1: Suggested CBR values for pavement materials for unsealed roads .............. 11 Table 3.2: Typical Clegg Impact Value (CIV)................................................................... 11 Table 3.3: Base strength versus Clegg Impact Value...................................................... 12 Table 3.4: Indicative permeability values (100% standard compaction) .......................... 12 Table 3.5: Typical properties for unsealed road wearing course ..................................... 15 Table 3.6: Typical specifications (South Africa)............................................................... 16 Table 6.1: Types of stabilisation ...................................................................................... 35 Table 6.2: Example calculation – blending two materials ................................................ 38 Table 8.1: Comparative rates of annual gravel loss ........................................................ 66 Table 8.2: US Army URCI scale and condition rating...................................................... 68 Table 9.1: Example life cycle analyses............................................................................ 77

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FIGURES

Figure 2.1: Layers associated with an unsealed road pavement........................................ 5 Figure 2.2: Class U1 road ................................................................................................... 6 Figure 2.3: Class U2 road ................................................................................................... 7 Figure 2.4: Class U3 road ................................................................................................... 7 Figure 2.5: Class U4 road ................................................................................................... 7 Figure 2.6: Class U5 road ................................................................................................... 8 Figure 3.1: Laboratory CBR test and 4.5 kg Clegg impact field test ................................. 11 Figure 3.2: Loose material and coarse texture due to surface wear................................. 12 Figure 3.3: Moisture range variation for compaction......................................................... 13 Figure 3.4: High quality unsealed road surface ................................................................ 15 Figure 3.5: Suggested PSD range for unsealed wearing course...................................... 16 Figure 3.6: Relationship between shrinkage product, grading coefficient and

performance of wearing course gravels.......................................................... 17 Figure 3.7: Workability attributes of granular materials..................................................... 18 Figure 4.1: Pneumatic traffic counting .............................................................................. 20 Figure 4.2: Traffic counts obtained from vibration sensors ............................................... 20 Figure 4.3: Design for granular pavements (80% confidence).......................................... 21 Figure 5.1: Pit material raised and transported to road bed.............................................. 25 Figure 5.2: Operation of ‘Rockbuster’ plant ...................................................................... 29 Figure 5.3: Static grid roller............................................................................................... 30 Figure 5.4: Jaw crusher .................................................................................................... 31 Figure 5.5: Gyratory crusher ............................................................................................. 32 Figure 5.6: Cone crusher .................................................................................................. 32 Figure 5.7: Impact crusher ................................................................................................ 33 Figure 5.8: Vertical shaft impact crusher .......................................................................... 34 Figure 6.1: Example combination particle size analysis ................................................... 37 Figure 6.2: Schematic of insoluble polymer encapsulating soil particles .......................... 39 Figure 6.3: Electron micrograph of acrylimide copolymer coating soil particles ............... 40 Figure 6.4: Vertical saturation test .................................................................................... 43 Figure 6.5: Purpose-built stabilisation binder spreader..................................................... 44 Figure 6.6: Application of liquid stabilisation binder with water truck ................................ 45 Figure 6.7: Adding granulated polymer using patented eductor ....................................... 45 Figure 6.8: Stabilisation binder mixing with purpose-built recycler ................................... 46 Figure 7.1: Advisory sign for dust hazard ......................................................................... 49 Figure 7.2: Mobile and static dust monitoring apparatus .................................................. 49 Figure 7.3: Schematic diagram of Colorado State University Dustometer........................ 50 Figure 7.4: Loss of fines increasing surface texture ......................................................... 51 Figure 7.5: Slurrying unsealed surface ............................................................................. 51 Figure 7.6: Loss of fine material leaving coarse gravelly surface ..................................... 52 Figure 7.7: Loose material between wheelpaths (note centre overlap from trafficking

in both directions) ........................................................................................... 52

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Figure 7.8: Measurement of loose material on pavement surface.................................... 53 Figure 7.9: Corrugation formation in dry climates ............................................................. 54 Figure 7.10: Corrugations in gravel surface (left) and sandy surface (right) ....................... 54 Figure 7.11: Corrugation formation in wet climates ............................................................ 55 Figure 7.12: Potholes on flat crossfall ................................................................................. 55 Figure 7.13: Dry rutting in wheelpath .................................................................................. 56 Figure 7.14: Surface gouging.............................................................................................. 56 Figure 7.15: Longitudinal scour on steep gradient.............................................................. 57 Figure 7.16: Transverse scouring on horizontal curve........................................................ 58 Figure 7.17: Longitudinal scouring between wheelpaths .................................................... 58 Figure 7.18: Snow and ice formation .................................................................................. 59 Figure 8.1: Patrol grading ................................................................................................. 60 Figure 8.2: Tow-behind steel drum roller and multi-tyred roller ........................................ 61 Figure 8.3: Surface slurrying during compaction .............................................................. 62 Figure 8.4: Wet compaction and slurrying (left) and dry compaction (right) ..................... 62 Figure 8.5: Surface after scarifier grading......................................................................... 63 Figure 8.6: Ground penetration radar (GPR) with horn antenna....................................... 64 Figure 8.7: Condition deduct values (drainage, cross-section, corrugations, dust) .......... 69 Figure 8.8: Condition deduct values (potholes, ruts, loose aggregate)............................. 70 Figure 8.9: US Army URCI calculation.............................................................................. 71 Figure 8.10: Pavement assessment example..................................................................... 71 Figure 8.11: US Army unsealed road condition assessment form...................................... 72 Figure 8.12: Roughometer .................................................................................................. 73 Figure 8.13: Laser Profilometer .......................................................................................... 73 Figure 9.1: Example life cycle analysis ............................................................................. 77 Figure 9.2: Life cycle analysis of sheeting life and grading intervention ........................... 78

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1 INTRODUCTION

1.1 Scope of Guide to Pavement Technology Part 6 Part 6 of the Guide to Pavement Technology addresses unsealed pavements technology and complements the ARRB Unsealed Roads Manual (Giummarra, Ed, in press). It also includes relevant technical information contained in other reports and documents.

Note that the ARRB Unsealed Roads Manual is a compilation in the one document of all aspects pertaining to the design, construction and management of unsealed roads for use by all authorities associated with unsealed roads e.g. Austroads members, local government, national parks, forestry commissions, etc. In contrast, Part 6 of the Austroads Guide to Pavement Technology covers unsealed roads technology.

Part 6 outlines those aspects of unsealed roads pertinent to unsealed road pavement technology, including:

operational demands of unsealed road surfaces

pavement configurations, floodways, cuts, fills and mine haul roads

identification of suitable pavement materials including commercially produced products and natural gravel sources

improvement of unsealed road pavement materials using modified stabilised materials

pavement design, including determination of required pavement thickness over the subgrade, drainage and erosion protection, and environmental considerations

performance expectation, including surface condition assessment

maintenance and rehabilitation and life cycle operating cost evaluations.

Topics related to unsealed roads and addressed in other parts of the Guide to Pavement Technology are listed in Table 1.1.

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Table 1.1: References to unsealed pavement technology in the Austroads Guide to Pavement Technology and ARRB Unsealed Roads Manual

Pavement material selection

Part 4: Pavement Materials Part 4E: Recycled Materials Part 4I: Earthworks Materials Part 10: Sub-Surface Drainage

Crushed unbound granular materials Part 4: Pavement Materials Part 4A: Granular Base and Sub Base Materials Part 4J: Aggregate and Source Rock

Stabilisation Part 4: Pavement Materials Part 4D: Stabilised Materials Part 4L: Stabilising Binders

Construction practice/specifications Part 8: Pavement Construction and Construction Assurance Part 9: Pavement Work Practices ARRB Unsealed Roads Manual

Maintenance practice Part 7: Pavement Maintenance Part 9: Pavement Work Practices ARRB Unsealed Roads Manual

Geometric design ARRB Unsealed Roads Manual

Asset management Part 5: Pavement Evaluation and Treatment Design ARRB Unsealed Roads Manual

Bituminous sealing of unsealed road pavements Part 3: Pavement Surfacings Part 4: Pavement Materials Part 4K: Seals

Table 1.2 lists relevant websites from which pertinent publications on technologies associated with unsealed roads such as technical notes, guidelines, work tips and safety data can be obtained. Also included in the guide is a bibliography of relevant publications.

Table 1.2: Key websites pertinent to unsealed road technology

Austroads www.austroads.com.au

ARRB www.arrb.com.au

NZ Transport Agency www.nzta.govt.nz

Australian Asphalt Pavement Association www.aapa.asn.au

Cement Concrete & Aggregates Australia www.concrete.net.au

Australian Stabilisation Industry Association www.auststab.com.au

PIARC www.piarc.org

Materials Safety www.msds.com.au

South African National Roads Agency www.nra.co.za

1.2 Guide to Pavement Technology The Guide to Pavement Technology consists of the following 10 parts:

Part 1: Introduction to Pavement Technology

Part 2: Pavement Structural Design

Part 3: Pavement Surfacings

Part 4: Pavement Materials

— Part 4A: Granular Base and Subbase Materials

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— Part 4B: Asphalt

— Part 4C: Materials for Concrete Road Pavements

— Part 4D: Stabilised Materials

— Part 4E: Recycled Materials

— Part 4F: Bituminous Binders

— Part 4G: Geotextiles and Geogrids

— Part 4H: Test Methods

— Part 4I: Earthworks Materials

— Part 4J: Aggregate and Source Rock

— Part 4K: Seals

— Part 4L: Stabilising Binders

Part 5: Pavement Evaluation and Treatment Design

Part 6: Unsealed Pavements

Part 7: Pavement Maintenance

Part 8: Pavement Construction

Part 9: Pavement Work Practices

Part 10: Subsurface Drainage

1.3 Unsealed Road Network Operation Australia has about 800,000 km of roads, of which about two-thirds are unsealed (Austroads 2000) whilst New Zealand has about 92,700 km of roads of which about 40% are unsealed (Transit New Zealand, Road Controlling Authorities and Roading New Zealand 2005).

The unsealed road network serves the community by providing:

access to rural and local communities, often in isolated locations

freight routes servicing primary and secondary industries

haul roads servicing the mining and timber industries

recreational, social and tourist pursuits

links for military use

emergency services access (e.g. fire fighting) in national parks, etc.

Compared to sealed roads, the performance of unsealed roads is typified by:

higher operating costs associated with surface maintenance and replenishment

restricted or no access during and after periods of heavy rainfall

higher accident risks per vehicle-kilometres travelled associated with corrugated, potholed, dusty, slippery (when wet) and loose (dry) surfaces

higher environmental and heritage (i.e. historical and indigenous) impacts associated with a high consumption of natural materials extracted from natural gravel pits

high demand for water associated with frequent maintenance operations.

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The purpose of this guide is to assist road authorities in the efficient management of unsealed road pavements. As well as addressing fundamental design issues, advice is provided on operational and strategic management issues such as:

braking and skidding associated with loose gravel on the road surface

visibility issues associated with the generation of dust

damage to vehicles (e.g. windscreens) associated with flying stones

optimising routine patrol grading to maintain an adequate riding surface

conservation of natural materials associated with maximising periods between re-surfacing

reduced environment and heritage impacts associated with less material extraction

reduced impacts on the roadside habitat associated with loose material.

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2 TYPES OF UNSEALED ROADS

2.1 Pavement Configurations and Classifications The quality levels of unsealed roads, and the associated levels of maintenance, vary widely across the network. They are principally based on the volume of daily traffic, the composition of the traffic (e.g. road trains), and accessibility and remoteness issues: pavement configurations vary from two-lane, multiple granular layers and shoulders constructed over the subgrade, to a single lane shaped subgrade.

In all cases in this guide, unsealed pavements refer to full depth granular pavements. Other pavement layers or wearing surfaces such as stabilised bound layers or light duty bituminous surfaces are not addressed.

There are four types of pavement layers associated with unsealed roads (Figure 2.1):

wearing course: sometimes referred as the ‘sheeting layer’; it is maintained with patrol grading and replenished after some years as its thickness is reduced and/or when a large amount of fine material has been lost as dust

base: provides structural support to the wearing course and protects against subgrade deformation

subbase: adds to the structural capacity of the pavement and makes up the desired thickness indicated from empirical thickness design charts

subgrade: the in situ soil or fill upon which the pavement is founded; it may also be used as a wearing course on access tracks.

wearing course (sometimes referred to as sheeting layer)

base

subbase

subgrade

Figure 2.1: Layers associated with an unsealed road pavement

At this time there is no agreed hierarchy of unsealed pavement types. However, a suggested Austroads classification is shown in Table 2.1 (Austroads 2006a). Photographs of typical roads associated with the five classes shown in Figure 2.2 to Figure 2.6.

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Table 2.1: Unsealed road classification

Class Daily traffic (typical veh/ day) Description Material quality and typical configuration

U1 >200

All-weather formed pavement with adequate drainage provided. At least two pavement layers over subgrade.

Granular or modified materials may be adopted in the base and wearing course. Dust suppressants may be incorporated in maintenance strategies.

Crushed quarry materials or in situ processed natural gravels.

20 mm max. size** wearing course, min. 100 mm thick.

40 mm max. size base, min. 150 mm thick. 55 mm max. size subbase, min. 150 mm thick.

U2 100 – 200

Mostly all-weather formed pavement with some drainage. Two pavement layers over subgrade.

Granular or modified materials may be adopted in the wearing course. Dust suppressants may be incorporated in maintenance strategies.

Crushed quarry materials, crushed pit material, ‘on road’ processed natural gravels.

40 mm max. size wearing course, min. 100 mm thick.

55 mm max. size base, min. 150 mm thick.

U3 20 – 100

Formed pavement with surface drainage. Max. of two pavement layers over subgrade.

Granular or modified materials may be adopted in the wearing course. Dust suppressants may be incorporated in maintenance strategies.

Natural gravels, pit materials or quarry wastes. 40 mm max. size wearing course,

min. 100 mm thick. 55 mm max. size subbase, min. 150 mm thick.

U4 < 20 Unformed pavement with single pavement layer

over subgrade. Natural gravels, pit materials or quarry waste. 50 mm max. size wearing course,

min. 150 mm thick.

U5 < 10 Unformed pavement comprising subgrade only. Vegetation cleared subgrade1.

In some circumstances, a wearing course may be incorporated as a thin binding course over subgrade (armouring to improve trafficability).

** refers to maximum stone size

Source: ARRB Group

Figure 2.2: Class U1 road

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Source: ARRB Group

Figure 2.3: Class U2 road

Source: ARRB Group

Figure 2.4: Class U3 road

Source: ARRB Group

Figure 2.5: Class U4 road

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Source: ARRB Group

Figure 2.6: Class U5 road

2.2 Selection of Pavement Type With the exception of mine and forestry haul roads and some access tracks, in most cases the construction of new unsealed roads is unlikely as the network is essentially established. Therefore the selection of a particular type of unsealed road pavement will generally be associated with upgrading an existing road surface to meet the intended use.

The main issues to consider in the selection of an unsealed road pavement are:

the volume and type of traffic (e.g. road trains) as this will govern the pavement thickness and quality of wearing course required

desired speed of traffic in relation to safety and dust emissions

the importance of the pavement in terms of all-weather access which may have social or economic impacts on communities and industries

the availability of local materials for the wearing course because the provision of inadequate materials can result in high maintenance costs.

As a guide, Table 2.2 suggests typical situations associated with the selected pavement types.

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Table 2.2: Indicative pavement type selection

Pavement type Traffic spectrum Attributes Typical applications

U1 >200 veh/day

and/or >20% heavy vehicles2

Up to 100 km/h1

two lanes plus shoulder

Main unsealed roads carrying significant freight or livestock.

Links to major resource developments, e.g. mines, gas fields, etc.

U2 100-200 veh/day

and/or >10% heavy vehicles

Up to 100 km/h two lanes plus shoulder

Main links between communities, national parks, recreational areas, haul roads.

U3 20-100 veh/day

and/or <10% heavy vehicles

Up to 80 km/h two lanes

Links between smaller communities, national parks, recreational and remote areas, haul roads within quarries/mines.

U4 <20 veh/day Up to 80 km/h

single lane

Main access to remote areas, difficult terrains and fire protection, national park access.

U5 <10 veh/day Up to 60 km/h

single lane

Minor access (four wheel drive or heavy duty vehicles) to remote locations, fire protection.

1 Speed is dependent upon terrain, road geometry and slipperiness/condition of wearing course (e.g. wet, gravelly or sandy).

2 Heavy vehicles are defined as Class 4 vehicles and above or mine haul trucks.

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3 PAVEMENT MATERIALS

In selecting a material specification for an unsealed pavement, attributes such as grading, plasticity and CBR are typically of a lower order than those for sealed roads because of the need to use locally available materials which are predominantly natural gravels. Whilst this is compensated for by generally low traffic volumes, it should be noted that some unsealed roads even with low traffic intensities must serve as vital transport links which require higher levels of serviceability than might not otherwise be considered.

The wearing course material needs to provide good wearing resistance which would otherwise lead to a high level of loose surface material, gravelly surfaces and corrugations. In addition, low permeability will reduce the likelihood of potholes, surface rutting and shoving and the related inaccessibility issues.

The properties of the underlying layers are more associated with strength (CBR) and workability to ensure that a reasonable degree of compaction is achieved. Compaction at optimum moisture content is often not possible because of the scarcity of water or the cost of carting water. The consequences of loss of shape (i.e. subgrade rutting as associated with sealed pavements) caused through the use of inferior CBR material, or insufficient structural pavement thickness, is less important in unsealed pavements as the surface is periodically reshaped by maintenance grading.

An ideal material for the wearing course of an unsealed road will have properties which result in an even, tight, relatively impermeable (erosion resistant) and wear resistant surface. The particle size distribution (PSD) and plasticity index (PI) will be such that there is sufficient coarse material to provide resistance to wear, adequate dry strength through mechanical interlock, fine particle bonding and low permeability to mitigate against loss of strength when the surface becomes wet. In addition, the soil fractions are required to have sufficient dry strength to hold aggregate fractions in place. This is to prevent ravelling and the development of loose material on the surface.

3.1 Basic Pavement Material Principles for Unsealed Roads The properties which affect the behaviour of a pavement material depend upon its skeletal structure and the nature of the stone aggregate and fine soil matrix. The principal factors affecting the performance of materials in relation to unsealed roads are:

stability (all pavement layers)

resistance to wear (wearing course)

impermeability (all pavement layers)

workability and compaction (all pavement layers).

3.1.1 Stability

This is the ability of a material to resist deformation, both vertically and laterally. Strength is an important component associated with the ability of a material to resist imposed stresses. Most common measures of strength involve an assessment of the shear strength of a material which is governed by the degree of aggregate interlock (particle friction) and cohesion (bonding of fine soil). The strength depends principally on its moisture and void (compacted density) content. Typical strength determinations include laboratory CBR testing (Figure 3.1), field testing using devices such as the Clegg Impact Hammer (Figure 3.1) and, to a lesser degree, field deflection tests such as the Falling Weight Deflectometer (FWD).

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Source: Standards Australia (2001) Source: ARRB Group

Figure 3.1: Laboratory CBR test and 4.5 kg Clegg impact field test

Typical CBR values for unsealed road pavement layers are shown in Table 3.1.

Table 3.1: Suggested CBR values for pavement materials for unsealed roads

Pavement layer Typical CBR (soaked)

Wearing course (gravel materials) Minimum 40

Base Minimum 50

Subbase Minimum 30

Note: These values are lower than those recommended for lightly-trafficked sealed pavements on account of more frequent patrol grading of unsealed surfaces.

Typical Clegg Impact Values (CIV) obtained using the standard 4.5 kg Clegg Impact Hammer for different materials are shown in Table 3.2.

Table 3.2: Typical Clegg Impact Value (CIV)

Material Type As-compacted CIV CIV after 2-4 days of drying

Non-plastic soft sandstone 30 <40

Normal well-graded base 30-35 >50

Plastic gravel <30 >60

Source: David Poli and Jim Crandell, personal communication, 2004

Sossic (1987) reviewed Main Roads WA Clegg test results and concluded there was a general relationship between CIV and base strength, as shown in Table 3.3. From this study a minimum base CIV of 55 was recommended for northern South Australia to provide adequate pavement strength.

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Table 3.3: Base strength versus Clegg Impact Value

Base Strength CIV

Very High >100

High 75-100

Medium to High 55-74

Low to Medium 30-54

Low <30

Source: Sossic (1987).

APRG Technical Note 13 (Austroads 2003) indicates a similar value of 50 or greater (characteristic from 6 to 10 locations) for the pavement base layer to ensure stability, and to avoid delamination of the surfacing and excessive deformation immediately after opening to traffic.

3.1.2 Resistance to Wear

The wearing surface should be compacted to produce a tight surface in which the aggregate is held in place as strongly as possible by the fine soil matrix as it is exposed to both weather and traffic forces. As fines are worn away (through the generation of dust) the texture of the surface becomes coarse and the aggregate is loosened, resulting in a very gravelly surface as shown in Figure 3.2.

Source: ARRB Group

Figure 3.2: Loose material and coarse texture due to surface wear

3.1.3 Impermeability

A relatively impermeable surfacing material is required to protect the underlying material from the entry of water and subsequent loss of bearing strength or stability. Although permeability can be measured directly, it is usually inferred from classification and index tests.

Typical permeability values are shown in Table 3.4 for 100% standard compaction tested under falling head conditions, i.e. according to test method AS1289 6.7.2.

Table 3.4: Indicative permeability values (100% standard compaction)

Material Suggested maximum permeability (m/s)

Unsealed wearing course 1 x 10-4

Base and subbase 1 x 10-3

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3.1.4 Workability and Compaction

The workability of a material relates to the ease with which it can be compacted to a desired density and the nature of the finished surface in terms of tightness and uniformity (no segregated and bony areas). In addition the moisture density relationship can be used in considering the section of a material in terms of the costs associated with the amount of water required to be brought to site.

The shape of the dry density-moisture content parabola, in terms of being steep or flat is an indication of the moisture sensitivity of a material and the moisture range in which the desired density can be achieved (Figure 3.3). A moisture content range of one-third of the OMC value either side of optimum is generally desirable.

0 2 4 6 8 10 12 14 16

Moisture Content %

Dry

Den

sity

Moisture range available to achieve compaction

Moisture required to be delivered to site

Source: ARRB Group

Figure 3.3: Moisture range variation for compaction

For a very steep density-moisture parabola, the moisture range is quite small. This is termed ‘moisture sensitive’ and compaction is best achieved by compacting higher than optimum with the material drying back through it. Materials which typically display steep parabolas are: (1) hard rocks with low fines content and no plasticity, and (2) blocky shaped aggregates and rounded river gravels. For these materials, compaction ‘back through optimum’ (i.e. starting compaction above OMC and completing below OMC) often produces satisfactory results.

For a flatter density-moisture parabola (generally associated with sands and clays), the moisture range is quite wide. As a result, it may be more easily compacted depending on plasticity, i.e. clays with high plasticity can be difficult to compact. These materials are preferably compacted dry of optimum in order that they dry quickly to prevent ravelling under traffic and do not induce excessive shrinkage cracking during the drying phase.

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3.2 Unbound Granular Specifications Specification requirements for unsealed road pavement materials are generally broader than in the case of sealed roads. However, the basic principles in terms of desired performance are the same, being based on the following three intrinsic components:

Particle size distribution (PSD), where strength is achieved from particle interlock and the maximum density principle (i.e. strength is directly related to density). The PSD also controls the permeability of a soil; particular emphasis is placed on the per cent material finer than 0.5 mm.

Plasticity, where the fine material contributes to densification of the aggregate through the reduction of interlock when wet and the provision of a cohesive strength to hold the aggregate in place when dry.

Aggregate hardness, where the aggregate is of sufficient hardness to resist significant breakdown under compaction and trafficking. In addition, a wearing course is required to have a durability level such that it does not break down when exposed.

3.2.1 Maximum Size and Particle Size Distribution

As the maximum aggregate size increases, the finished surface will generally become more open-textured (‘bony’) causing the surface to quickly ravel, leaving loose gravel on the surface. Therefore the larger the aggregate maximum size the more important it is to provide a uniform grading to interlock aggregate sizes in place and produce a lower-permeable surface.

In general, materials with a maximum size greater than 40 mm are only suited to base and subbase layers rather than the wearing course. However, in some instances aggregate sizes greater than 40 mm can be used in the wearing course if the source rock is soft (typical LA abrasion >50%) or if an excess of fines (>30%) is present.

Wearing Course (Sheeting Layer)

Traditional pavement material specifications for sealed roads will generally be unsuited to unsealed road applications as a wearing course as they are typically low in plasticity and fines content and the aggregate fractions will ravel very quickly. Therefore, whilst maintaining a uniform grading for workability and high compaction achievement, unsealed road pavement materials will have higher fines content and plasticity.

A good unsealed wearing course is shown in Figure 3.4.

A guide to suitable gradings for wearing surfaces for unsealed pavements is presented in Table 3.5. This is a modification of data from NAASRA (1980), which has been superseded by Part 4A of the Guide to Pavement Technology (Austroads 2008a).

The PSD envelope shown in Figure 3.5 suits all maximum particle sizes below 55 mm, e.g. 40 mm through to 20 mm. In the case where the maximum size is below 20 mm, the distribution of sizes below the maximum size (i.e. 2.36 mm, 0.425 mm and 0.075 mm) remains unchanged. For maximum particle sizes above 55 mm, the PSD limits from 26.5 mm and below are appropriate.

The following website also gives further guidance on the desirable properties of unsealed surfaces: http://www.transport-links.org/transport_links/filearea/documentstore/Draft Gravel Guidelines.pdf

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Source: ARRB Group

Figure 3.4: High quality unsealed road surface

Table 3.5: Typical properties for unsealed road wearing course

Sieve size (mm) Per cent passing for all maximum sizes

55 100

37.5 95-100

26.5 90-100

19 80-100

2.36 35-65

0.425 15-50

0.075 10-40

Plasticity

Less than 500 mm annual rainfall – max. 20 More than 500 mm annual rainfall – max. 12

OR Weighted Plasticity Index (PI x % passing 0.425)

Max. 500 for low rainfall Max. 250 for high rainfall

4 day Soaked CBR Minimum 40%

Source: based on NAASRA (1980).

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0

10

20

30

40

50

60

70

80

90

100

0.01 0.1 1 10 100

Particle size mm

Per

cen

t F

iner

Source: based on NAASRA (1980)

Figure 3.5: Suggested PSD range for unsealed wearing course

Performance-Related Specifications for Wearing Course

As an alternative to the above ‘recipe’ type specifications, performance-related data produced in South Africa (South Africa Department of Transport, 2009) can be a useful guide to the anticipated performance of a material which may or may not comply with a recipe specification (Table 3.6).

The specification is based principally on two characteristics, i.e.:

Shrinkage Product: [Ls = Linear shrinkage, P0.425 = per cent passing 0.425 mm] 425.0SP P . L S =

Grading Coefficient: ( )

100

P.PPG 75.40.25..26

c−= [P26.5, P4.75, P2.0 = per cent passing sieve sizes]

Table 3.6: Typical specifications (South Africa)

Characteristic Rural roads Urban roads Haul roads

Maximum size 37.5 mm 37.5 mm 75 mm

Oversize index 1 ≤ 5% 0 ≤ 10%

Shrinkage product 100-365 100-240 100-365

Grading coefficient 16-34 16-34 16-34

Treton Impact 2 20-65 20-65 20-65

Soaked CBR ≥ 15 ≥ 15 ≥ 40

1 The percentage of material retained on a 37.5 mm or 75 mm sieve.

2 A drop hammer crushing test.

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The relationship between shrinkage product and grading coefficient in terms of anticipated performance is shown in Figure 3.6. Note, although the specifications in Figure 3.6 are applicable to most materials and roads in Australasia, local investigations may show that the recommended limits can be adjusted based on local traffic and climatic conditions.

0

50

100

150

200

250

300

350

400

450

500

0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48

Grading Coefficient

Shr

inka

ge P

rodu

ct

D Slippery

AErodible

CRavels

EGood

BCorrugates and ravels

Sandy clays

Silts

Clayey gravels

Silty gravels

Sandy gravelsSands

0

50

100

150

200

250

300

350

400

450

500

0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 42 44 46 48

Grading Coefficient

Shr

inka

ge P

rodu

ct

D Slippery

AErodible

CRavels

EGood

BCorrugates and ravels

Sandy clays

Silts

Clayey gravels

Silty gravels

Sandy gravelsSands

Source: based on South Africa Department of Transport (2009, Figure 7).

Figure 3.6: Relationship between shrinkage product, grading coefficient and performance of wearing course gravels

Each zone in Figure 3.6 can be described as follows:

A Erodible Comprises sandy and clayey silts with insufficient plasticity to provide tight

bonding. Erosion sensitive with crossfall runoff and inclines.

B

Corrugates and ravels

(you had Ravels and corrugates)

Comprises sands and sandy gravels with little plasticity; therefore aggregate becomes loose (ravelling) and corrugations develop from vehicle suspension

oscillation. Can also erode in high rainfall areas.

C Ravels Comprises coarse gravels with little fines or plasticity to bind the aggregate and

therefore ravels quickly.

D Slippery Comprises silty clays and clayey gravels with high fines content producing slippery surfaces when wet.

E Good Comprises well-graded soil aggregate mixes with sufficient plasticity to bind

aggregate fractions into a hard wearing tight surface. Higher fines content can produce a dusty surface.

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3.2.2 Base and Subbase

These layers are designed as the structural capacity of the pavement. They support the unsealed wearing course and protect the subgrade from deformation. The principal performance attributes of these pavement layer materials are no different to those required of conventional unbound pavement materials for bituminous sealed pavements and detailed in the Guide Pavement Technology, Part 4A (Austroads 2008a).

For base and subbase materials, greater emphasis is placed on material availability and assessment in terms of performance attributes as illustrated in Figure 3.7, with soaked CBR being greater than 40%.

For the performance illustrated in Figure 3.7, the PSD requirements for unsealed road bases and subbases may fall on the finer side of the ‘light traffic’ zone but slipperiness will be more dependent upon plasticity and the percentage of aggregate (coarser than 2.36 mm).

Source: Wooltorton (1947)

Figure 3.7: Workability attributes of granular materials

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4 PAVEMENT THICKNESS

The structural thickness design of unsealed road pavements requires the provision of sufficient thickness to spread the traffic load such that it does not over-stress and deform the natural subgrade. In addition, consideration of increasing or decreasing thickness requirements may take into account:

the quality of material locally available being unable to meet a desired CBR, which implies a greater thickness over the subgrade at lower CBR values

the degree of patrol grading that may be economically employed (compared to increased thickness or improved materials) to effect any shape correction associated with subgrade deformation.

4.1 Thickness Design Methodology Thickness design methodologies are no different to those for sealed roads with thin bituminous surfacings (Austroads 2008b), viz:

determine the design traffic value, i.e. the number of equivalent standard axles (ESA)

determine the design CBR of the subgrade

use the design traffic ESA and the design CBR value to determine the pavement thickness from the thickness design curves – noting that the thickness design provides a means of using material with CBR less than 30 (typically) in lower layers of the pavement to achieve the desired thickness.

For a given traffic of known volume and load, a pavement’s ability to perform is dependent on three main factors:

pavement materials performance

the presence of excess moisture which adversely affects most materials

subgrade support stiffness.

At the design stage, the issue of materials performance is met by the selection of materials of appropriate quality for the varying roles that they play in the pavement structure. It is of considerable importance that, during construction, the assumptions made regarding material quality during the design process are satisfied. The materials must be strong enough to support the load and reduce the stress on the subgrade without causing serious rutting of the top layer by deformation of the subgrade.

Most pavements contain measures to control the ingress of water into the pavement structure. The provision of a high crossfall (4-6%), a wearing surface that is tightly bound, table drains, cross drains and, if necessary, sub-surface drainage (or moisture barriers) will reduce the influence of water on pavement performance.

The remaining factor, subgrade support, is in many respects beyond the control of either the designer or the constructor. However it is a key factor influencing pavement thickness design and careful assignment of the design CBR value to represent in-service subgrade strength is essential. This may be evaluated by field and/or laboratory testing and/or experience and should include consideration of the most severe subgrade moisture conditions that will occur.

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4.1.1 Design Traffic

Estimates of traffic loading (ESAs) are determined in accordance with Austroads (2008b) which identifies traffic loading in terms of road class. As for sealed roads, the freight activity on unsealed routes can vary significantly and the number of heavy vehicles and ESA/HV need to be correctly assigned to ensure the Design Traffic calculation is sound.

On-site traffic counting can be undertaken to provide improved estimates of traffic loading, either manually by visual logging or automatically from pneumatic counter strips (Figure 4.1) and vibration sensors attached to stock grids (Figure 4.2).

Source: ARRB Group

Figure 4.1: Pneumatic traffic counting

Source: DTEI

Figure 4.2: Traffic counts obtained from vibration sensors

4.1.2 Thickness Design

The Guide to the design of new pavements for light traffic (ARRB Transport Research 1998) provides pavement thickness design curves for both sealed and unsealed residential streets and rural roads of low structural integrity with granular materials. These charts are based on a probability level of 80%, i.e. a 20% risk of rehabilitation (i.e. renewing the wearing course for unsealed roads) of the pavement being required before the end of the design life (Figure 4.3).

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Source: ARRB Transport Research (1998, Figure 13.8.2.C)

Figure 4.3: Design for granular pavements (80% confidence)

The thickness determined from Figure 4.3 represents a minimum structural thickness to protect the subgrade from deformation (rutting) under trafficking during its design life. It is recognised however that during the selected design period the unsealed wearing course will reduce in thickness due to gravel loss resulting in a loss of structural thickness. Whilst this loss of thickness may result in surface deformation, it is recognised that routine patrol grading will reshape the surface. However, dependent upon the rate of attrition of the wearing course (Section 8.3) and frequency of patrol grading, the designer may wish to include an additional ‘sacrificial’ thickness to the pavement.

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5 PAVEMENT MATERIAL SOURCES

A number of material sources may be available for the construction of unsealed road pavements, including natural local materials and quarry by-products that may not be appropriate for sealed pavement construction. These sources can provide a viable low-cost construction option. Any comparison of costs should include all components of purchase, raising, processing, haulage and placement of the material per unit area of the pavement to achieve the required quality of construction.

Natural materials can include weathered rock, concretionary rock profiles and natural gravels; they may require some level of processing and/or blending to create a suitable product.

Considerations on the selection of both source and material attributes are presented in detail in the Guide to Pavement Technology: Part 4 – Pavement Materials (Austroads 2007).

5.1 Borrow Pit Geological Sources Borrow pits used in association with unsealed road materials in Australia and New Zealand are sourced principally from the following geological deposits.

5.1.1 Residual Deposits

Residual deposits are formed in situ from the surface weathering of the parent rock. Generally these can be raised by mechanical means (bulldozer, excavator, etc.). Typically, a weathering profile displays a gradational change from clays and fine size particles near the surface to competent and fresh rock at depth. With increasing depth there are increases in particle size, stone angularity and hardness, and decreases in clay content and reactivity. The depth to which a deposit is worked (notwithstanding limits imposed by regulation, etc.) can be a balance between:

the nature of the underlying rock and the weathering profile

the ability of the equipment available to operate the deposit and, if necessary, process the material

the quality and properties of the pavement material required.

5.1.2 Colluvial Deposits

Colluvial deposits are formed toward the base of slopes as aprons and fans. They are often coarse and thick where there is a marked change in gradient topography. They will reflect the geology of the weathering profile and the underlying rock of the slope above the deposit. There may be some differentiation of material quality across the deposit, with finer materials being more prevalent on the outer extents. The extent of working of the deposit can depend largely on the distribution of the material quality.

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5.1.3 Alluvial Deposits

Alluvial deposits are typically formed in river beds and alluvial fans from the settling-out of particles carried by stream flow. Material in these deposits can be derived from a number of separate source environments. They will display more of the features of transportation, namely particle sorting and rounding. Generally, the deposits are comprised of lenses or scour and fill structures which contain particles of similar size and which, individually, may not be suitable. In combination, and when mixed, the different size materials may produce a suitable end-product. These types of deposits may not have high levels of clays and silts because the finer size materials do not settle out at the same rate as coarse particles. Generally these deposits require working over a significant area to achieve a uniform distribution of particle sizes. Processing by way of crushing to restore some angular particle shape (for particle interlock/stability in the pavement), or blending to introduce some fines and plasticity, may be necessary.

5.1.4 Concretionary Deposits

Concretionary deposits are formed as immediate subsurface deposits by cyclical concretionary cementing action. Various stages of maturity can occur, ranging from small rounded nodular gravels through increasing gravel size to continuously cemented sheets. The material type, amongst others, could be ferruginous (buckshot or pea gravel, laterite), siliceous (gibbers or silcrete) or calcareous (nodular limestone or calcretes).

The concretionary cementation zone may be underlain by a softer leached zone and the interface could be gradational. Nodular gravel forms have rounded particles that may not interlock in a compacted pavement and hence are unstable or produce a ‘floating’ surface. The massive forms can be sufficiently thick and continuous that they require drill and blast methods for raising material. The depth to which a deposit is worked may be dictated by, and can dictate, the quality of the material product.

5.1.5 Volcanic Deposits

Volcanic deposits are formed as igneous deposits by the settling of pyroclastic detritus, ash or cinder as volcanic tuff or scoria (vesicular) with possibly some welding of the particles. Intrinsically this material may have little or no plasticity but could display unsoundness once raised due to secondary mineralisation.

These deposits can generally be termed ‘soft’ rock deposits, which can be used to describe the in situ condition of a rock mass that can be raised with mechanical equipment. It is most suited to unsealed road material sources.

In contrast, ‘hard’ rock deposits require quarrying in terms of blasting and crushing. They can include the harder and more massive forms of calcretes and ferricretes which are found in ‘soft’ rock terminology. Unless sufficient plasticity and fines can be generated from the quarrying process, or the blending of other material is possible, hard rock quarries (with the exception of some overburden or waste products) are not always suited to unsealed road wearing courses because they lack binder and ravel under traffic.

5.2 Winning of Local Materials from Borrow Pits 5.2.1 Overview of Regulations

The raising of construction materials generally is considered as an ‘extractive mining’ operation and regulations regarding access to, and winning of, local materials for road construction vary in detail between the states and territories of Australia and in New Zealand. Following are some of the more general aspects of these regulations.

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Landowner's Consent

Authorities in the various Australian states may have a range of powers available to gain access to property and remove material. The extent to which these powers are exercised by the authority may be a matter of policy for the authority or the government according to the circumstances. Actions without the consent or approval of the landowner may result in a court challenge, leading to additional costs and/or delays. A formal agreement negotiated with the landowner may be required.

There may be statutory limitations on the types of areas that can be accessed (typically proximity to dwellings, stock watering points, orchards, etc. defines exemption from pit operation) without specific approval from the landowner. Commonly a landowner is entitled to compensation or royalty, subject to the vested ownership of the minerals (rock), for loss of productivity from the land affected. The payment negotiated may be based on a rate for the area of land affected or a rate per unit mass of the material removed.

An alternative to operation by an authority is for the site to be developed as a mining tenement, in which case there are similar procedures to be followed and approvals required.

Landowners frequently have a good knowledge of the ground conditions and history of their property or even an area generally. They can be very useful sources of information if they are co-operative.

Council Planning Regulations

Council planning schemes will indicate the zones where extractive industries are not permitted. Applications for permits to open a pit in other areas will be considered by Councils on the grounds of certain parameters (visual amenity, water supply contamination, etc.). Councils may place conditions on the permit to safeguard nearby residents or to protect existing infrastructure.

In the case of a pit (or quarry) on private property, councils may impose conditions on the granting of a Planning Permit including, but not necessarily limited to:

construction of haul road and maintenance – to eliminate dust nuisance to the landowner

fencing haul route – to protect stock

adequate compensation for a neighbour where the haul route continues through the neighbour's property

rehabilitation of the pit area, including fencing off from stock while vegetation is being generated

stockpiling of stripped topsoil – to assist in rehabilitation

construction of silt ponds downstream of the pit – to prevent turbidity in nearby streams

prohibition of carting at certain times of the year.

These circumstances may also occur where the council, as the planning authority, will also be the operator of the pit or quarry.

Where there is a considerable quantity of gravel to be hauled over council roads, it is possible for the council to place certain conditions on the permit for the operation. These may include:

the need to restore the public roads to the 'pre-carting' condition as determined from joint inspections by council and operator representatives (which is usually sufficient on unsealed and low volume roads)

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in the case of a sealed road, the payment of a fee to the council for the additional maintenance during the operation, and for the shortened life of the road due to the increased amount of axle loading as calculated for a life cycle analysis.

These issues emphasise the importance of minimising haul and using nearby materials where possible. When deciding on the most economic material, total costs have to be taken into account. However, in general, the closest satisfactory material (not the best available in the locality) will be economic even if this means opening a new pit near the works site.

State or Territory Government Regulations

State government regulations usually prohibit extraction from specific areas (coastal protection zones, reserves, etc.). State authorities (forestry, lands, conservation, environmental protection, etc.) may issue permits to remove material from Crown land subject to arrangements pertinent to the operation and its locality. The size and nature of an extractive mining operation might also dictate the need for licensing and the imposition of regulations under mining legislation. Aboriginal heritage, traditional land ownership or native title claims may also require consideration.

Federal Government Regulations

Federal government regulations may also apply to state and territory government regulations in relation to Native Title and Aboriginal heritage (artefacts, sacred sites, etc.).

5.2.2 Pit Operation and Rehabilitation

Pit Operation

A material borrow pit is only a temporary land use; clear operation and rehabilitation objectives, consistent with the proposed future land use of the area should be defined. From the outset these objectives should be established in consultation with relevant government departments, local councils, landowners, etc. There may also be a requirement to prepare an Environmental Management Plan that covers the removal of the material and the rehabilitation of the pit on completion. Figure 5.1 illustrates material raised in the pit and transported to the roadbed.

Source: ARRB Group

Figure 5.1: Pit material raised and transported to road bed

This plan should detail the extent of the extraction work, both in area and volume, and identify at which time, and for how long, sub-sections of the pit area are to be progressively worked over the expected life of the pit. Details of progressive rehabilitation/revegetation should also be provided in the plan.

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The access and haul road network established for the operation of the pit should also be considered as part of the works and included in the restoration and rehabilitation activities. In some instances, however, landowners may request that parts of this infrastructure remain because they provide improved access for their land activity.

The following procedures are typical of good practice, in addition to promoting safe operation and consideration of future rehabilitation. Where the topography allows, note the following procedures:

Collect native vegetation seeds (if appropriate) for reuse later.

Strip native vegetation and stockpile for reuse as mulch.

Strip and remove topsoil to a location where it may be stored loosely in heaps, preferably not more than 2 metres high to ensure continued soil 'activity'. This should be replaced and replanted after use of the pit is completed. Progressive stripping and using topsoil overburden directly for rehabilitation of worked-out areas will reduce double handling. It will also have the potential to keep the vegetation active to assist regrowth rather than cause it to be sterilised by being stockpiled.

Work the pit clear of a major gully and prevent runoff water from entering the pit by diversion drains.

Water from the pit floor and cut-off drains should be directed to a silt pond before being discharged to a watercourse.

Work the pit in a manner that the pit floor drains away from the face; ponding of water at the face can disrupt the mining operation and influence the moisture regime of the material.

Ensure the pit is kept free of weeds by monitoring the cleanliness of equipment entering the pit and maintaining weed control on stockpiles, etc. This can ensure that weeds will not be dispersed throughout the vicinity with the gravel carted from the pit.

Because most natural materials are variable, mixing and blending to obtain a homogeneous mixture will usually be required. The layout and working plan of the pit should be influenced by the geology of the site to ensure consistent and acceptable material quality. The working face should be oriented to intersect the variety of material quality in the pit rather than be located in a single form of the material. Also, it is important to work the full depth of the face in the pit, and then move material parallel to the face to ensure thorough mixing. If placed unsorted on the road formation, windrowing and cross-blade mixing with a grader will be required.

The material, as raised directly at the pit face, may not be immediately usable and may require processing (e.g. size knockdown/reduction or additive blending). This may be done in the pit if there is sufficient room or else a separate working area or pad may be required. Alternatively, it may be possible to do this directly on the road formation.

Size knockdown/reduction can be achieved by removing the oversize material by separating out the larger particles (screening, etc.) or by processing (crushing or breakdown, etc.). Portable screening systems are available (power screens, grizzlies, etc.) that will scalp off the oversize particles without significantly influencing the smaller fractions of the material and the material properties like Atterberg limits, etc. A number of size knockdown systems are available, including portable crushing (and screening plants), rock busters and grid rolling (refer Section 5.3).

The moisture content of the material in the pit may be used to advantage, for example, if the material is moved to the construction site with minimum time where it could be allowed to dry back. This could reduce the amount of watering that is required to achieve the required OMC level for compaction.

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Pit Rehabilitation

There is a range of legislation concerned wholly or in part with matters related to site rehabilitation. Administrative arrangements between government agencies differ from State to State and country. Liaison between these agencies should, in the first instance, be via the local government and state/territory Departments of Mines or Environment or in accordance with State administrative procedures for material extraction.

The rehabilitation program may involve:

restoration of the area so that pre-extraction conditions are replicated

reclamation of the area so that the pre-extraction land use and ecological values can be re-established in similar conditions

remodelling of the area so that it is returned to a use substantially different, and perhaps nominally better, to that which existed prior to extraction.

Regulations may require that the landowner ‘sign off’ on acceptance of the final condition of the rehabilitated site.

The risk of soil erosion increases with rainfall intensity, particularly where vegetation has been removed. The final objective of rehabilitation of the site should be reinstatement to a safe and stable condition. On land used for agriculture or forestry, the aim could be to reinstate the land to its pre-extraction level of productivity or better. At the very least, the objective should be to restore the area as nearly as possible to its original condition.

A survey of the site is essential to provide a baseline standard for later rehabilitation. The significance of various factors will vary between sites: climatic conditions, particularly rainfall and soil characteristics, are invariably of direct significance to site rehabilitation procedures.

A site survey should include information on:

land form and surface geology including soil types

surface and ground water

land use

flora and fauna.

Even on a relatively small scale, the quarrying of materials can result in local changes to the physical environment such as effects on vegetation and surface and groundwater, and also in terms of the potential for dust. These changes need to be managed so environmental impacts such as erosion by wind and water, the introduction of weeds and the degradation of the visual amenity can be avoided.

Care is required in the removal and storage of topsoil and overburden. Many of the potential adverse impacts of materials extraction from pits and quarries can be avoided or reduced by the careful siting of access roads and the creation of buffer zones. In some cases sealing the access haul road may be necessary or the installation of grids at exit points for 'shakedown' to remove loose material from the haulage vehicles.

Good planning and operating procedures will minimise the adverse impacts of the extraction operation. 'Rehabilitation' refers to the operations whereby the unavoidable impacts on the environment are repaired. To the extent practicable, rehabilitation should be concurrent with extraction, particularly on larger pits and quarries.

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The following basic procedures should be followed:

Prepare a rehabilitation plan before commencing extraction (this may be a mandatory requirement) and be aware of any statutory requirements and ensure that these are met in the plan.

Locate the excavation so as to minimise visual exposure to passing traffic.

Always remove and retain topsoil for subsequent rehabilitation; progressive stripping of new areas with the concurrent rehabilitation of exhausted areas will minimise soil deterioration by stockpiling and reduce double handling.

Rehabilitate the site progressively wherever possible.

Ensure the site is made safe; restrict public access where possible.

Reinstate natural drainage patterns where they have been affected.

Ensure the reshaped land is formed so as to be inherently stable, adequately drained and suitable for the desired long-term use.

Minimise long term visual impact by creating landforms compatible with the landscape or away from view by passing traffic.

Be aware that topsoil will generally not hold on slopes steeper than 1 in 3.5 (27º) and cannot normally be placed by machine on slopes greater than 1 in 5 (19º). Consider the timing of rehabilitation and revegetation activities to optimise the use of natural weather conditions conducive to the regrowth cycle of vegetation.

Minimise erosion by wind and water during both the extraction and rehabilitation processes.

Remove all facilities and equipment from the site unless approval has been obtained from the regulatory authorities or affected land holders to do otherwise.

Remove all rubbish.

Revegetate the area with plant species that will control erosion and provide vegetative diversity compatible with the local ecosystem.

Prevent the introduction of weeds and pests. In some areas, notably Western Australia and South Australia, 'dieback' fungal organisms can be a major problem requiring particular care in topsoil clearing and storage.

Monitor rehabilitated areas until they are self-sustaining or at a stage which meets the satisfaction of the landowner or responsible government instrumentality.

5.3 Processing Material from Borrow Pits Material extracted from borrow pits may need processing in order to achieve suitable properties like PSD and Atterberg limits. PSD is generally associated with breaking down oversized material to a maximum size of 50 mm or smaller. Atterberg limits may be modified by the addition of additives or by otherwise adjusting the quantities of the finer PSD components.

The processing of the material can be undertaken either at the pit face, on a specially prepared pad, or on the road.

Note that all works associated with the mechanical break-down of rock particle sizes are subject to Australian workplace guidelines associated with safe exposure to silica dust. The guidelines can be found in state government authority regulations e.g. National Occupational Exposure Standard (NES) for Respirable Crystalline Silica Dust (Australian Government 2004).

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5.3.1 Processing on the Road Bed

There are principally two types of machinery in common use: the ‘Rockbuster’ and the grid roller. All rollers are capable of causing some degree of material breakdown, depending on the mass of the roller, the contact pressure and the hardness of the material particles.

Rockbuster

The ‘Rockbuster’ is a patented plant item which is basically a ‘tow behind’ or tractor-mounted hammer mill as shown in Figure 5.2. Modern ‘Rockbusters’ have at least 200 kW power capacity: the hammer shaft weighs nearly 2 tonne, on which 20 kg hammers are attached. The hammer speed in rotation is about 200 km/h. Typical production rates are of the order of 1,000 m3/day. The equipment can handle all types of rock sources but may be susceptible to high wear rates with more abrasive (siliceous) materials.

There is a limitation on the size of the particles that the machine can process. The hammermill action of the ‘Rockbuster’ will act on all the material that it passes over, breaking down both large and small particles. There is the potential to ‘over crush’ a material and create too many fines in the product. It may be necessary to rill out only the larger particles in a material and process these with the ‘Rockbuster’, with the crushed material then blended back into the original product.

Source: Broons Hire (S.A.) Pty. Ltd.

Figure 5.2: Operation of ‘Rockbuster’ plant

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Grid Roller

The grid roller is manufactured as a heavy mesh drum (Figure 5.3). It is designed to produce a high contact pressure and then to allow the smaller particles resulting from the breakdown to fall clear of the contact zone. The grid roller is often towed behind steel-tracked vehicles which also will break down a coarse material.

Source: ARRB Group

Figure 5.3: Static grid roller

5.3.2 Mobile Plant Crushing

The crushing of borrow pit material with a mobile crushing plant is becoming more popular for unsealed road material supply. This may be as a single crusher unit or, in the other extreme, a multi-stage crushing and screening plant. This can depend not only on what end-product is required and the economics of supply but also on the type of plant that is available at the time required. This operation permits high production rates (up to 400 tonne per hour) whilst also producing a consistent, graded product which is often easier to handle and place.

Further details regarding quarrying and aggregate production can be found in: <www.in.gov/dot/div/testing/manuals/aggregate/chapter 05.pdf>

Mobile crushing plants are commonly available either as self contained track-mounted, or semi-trailer modules.

There are six principal types of rock crushers used in the manufacture of road construction materials:

jaw crushers

gyratory crushers

cone crushers

impact crushers

hammer mill crushers

vertical shaft impact crushers.

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All crushing relies on either compressing rock particles between two metal surfaces or by the high-speed impact on, or by, rock particles against hard surfaces. Depending on the type of material being crushed, there are some characteristics, such as particle shape and Atterberg Limits, which can be influenced by the inherent nature of the rock. The selection of the appropriate crusher type can modify these characteristics to some extent in the final product.

Jaw Crusher

The basic style of crusher is the jaw crusher (Figure 5.4). It consists of two hardened metal plates with a tapering gap between them. One metal plate is fixed (fixed jaw) and the other (swing jaw) oscillates, causing the taper to alternately open and close. In simple terms, the feed particles fall into the taper to the point where the open jaw separation matches their size; as the taper then closes, the particle is compressed and fractures. The broken particles then drop further down the taper either to be caught again or eventually fall through the gap at the bottom of the taper. The eventual maximum size of the material is controlled by the gap. Some particle-to-particle crushing occurs in the process; this is more likely to occur if the crushing chamber is kept full.

Source: Pennsylvania Crusher Corporation

Figure 5.4: Jaw crusher

Gyratory Crusher

The gyratory crusher (Figure 5.5) uses an eccentrically-mounted tapered spindle which rotates within an inverted static cone. The rotary oscillation of the spindle causes a progressive rotary closure of the gap between the cone and the spindle. The profile between the crushing surfaces is similar to that of the jaw crusher and the crushing process is similar.

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Source: FLSmidth Minerals Source: Metso Corporation

Figure 5.5: Gyratory crusher

Cone Crusher

Cone crushers (see Figure 5.6) operate in a somewhat similar fashion to the gyratory crusher. However, a significant difference is the shape of the crushing surfaces (cone and mantle) and the crushing chamber. The longer chamber shape and flatter lying orientation causes a higher degree of stone-to-stone contact which results in the production of finer particles by grinding action rather than breakage by direct particle compression. This type of compression crusher is considered to be more suited for the production of more material in the fine particle range as well as more equant-shaped particles. A variety of cone and mantle profiles are available to suit the properties of various rock types and perhaps modify their inherent crushing characteristics according to product requirements.

Cone

Feed Feed

Discharge

Sizing gap

Discharge

Eccentric rotation

Cone

Feed Feed

Discharge

Sizing gap

Discharge

Eccentric rotation

Source: Boral Australian Construction Materials

Figure 5.6: Cone crusher

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Impact Crushers

Impact crushers rely on the high-speed impact of rock particles against a hardened metal surface (Figure 5.7). This can be achieved either as a hammer (or bar) striking the rock particle or the particle, having been accelerated, striking a static anvil. According to the strength and structure of the particles, the impact causes fracture or (partial) pulverisation of the particle. Pulverisation tends to cause the rounding of particles with finer-sized material being the result of the breakdown. Impact crushers are particularly susceptible to abrasive material and can suffer high wear rates.

Source: Pennsylvania Crusher Corporation

Figure 5.7: Impact crusher

Hammer Mill Crushers

Hammer mill crushers consist of a series of hammers or bars attached to a rapidly-rotating horizontal shaft. Particles fed into the crusher are struck by the hammers and, consequently accelerated by the impact, will strike a static anvil. The impacts can cause breakage or pulverisation of the particles. Particle size control can be adjusted by controlling the size of a discharge aperture.

Vertical Shaft Impact (VSI) Crushers

VSI crushers consist of a rapidly-rotating, vertically-mounted rotor into which rock material is fed (Figure 5.8). The rotation accelerates the particles horizontally through discharge ports in the rotor causing them to impact against an anvil surface. With high-speed rotation, the rock discharge from one port will strike rock that has been discharged from a previous port, thus causing a high level of rock-to-rock impact. A modified version of the VSI can involve feed rock cascading through the impact zone; a similar end result will be achieved.

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Source: Boral Australian Construction Materials

Figure 5.8: Vertical shaft impact crusher

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6 STABILISATION OF UNSEALED ROADS

6.1 Types of Stabilised Materials In the past, stabilised materials have been identified in terms of the type of binder used, e.g. cemented materials, lime stabilised materials, bitumen stabilised materials, etc. However, Part 4D of the Guide to Pavement Technology – Stabilised Materials (Austroads 2006b) – recommends an alternative categorisation based upon the type of material stabilised and its performance attributes associated with design, viz.:

subgrade stabilised materials

granular stabilised materials

modified stabilised materials

bound stabilised materials.

The associated properties of modified and bound stabilised materials can be obtained using various binders, quantities of binder or combinations of these. Table 6.1 summarises the types of stabilised materials, typical strengths achieved after stabilisation, how they are commonly achieved and performance attributes associated with the classification.

Table 6.1: Types of stabilisation

Category of stabilisation

Indicative laboratory strength after stabilisation

Common binders adopted Anticipated performance attributes

Subgrade CBR1 > 5%

(subgrades and formations) Addition of lime. Addition of chemical binder.

Improved subgrade strength. Improved shear strength. Reduced heave and shrinkage.

Granular 40% < CBR1 < +100%

(subbase and basecourse)

Blending other granular materials which are classified as binders in the context of this guide.

Improved pavement stiffness. Improved shear strength. Improved resistance to aggregate

breakdown.

Modified 0.7 MPa < UCS2 < 1.5 MPa

(basecourse)

Addition of small quantities of cementitious binder.

Addition of lime. Addition of chemical binder.

Improved pavement stiffness. Improved shear strength. Reduced moisture sensitivity, i.e.

loss of strength due to increasing moisture content.

At low binder contents can be subject to erosion where cracking is present.

Bound UCS2 > 1.5 MPa

(basecourse)

Addition of greater quantities of cementitious binder.

Addition of a combination of cementitious and bituminous binders.

Increased pavement stiffness to provide tensile resistance.

Some binders introduce transverse shrinkage cracking.

At low binder contents can be subject to erosion where cracking is present.

1. Four day soaked CBR.

2. Values determined from test specimens stabilised with GP cement and prepared using standard compactive effort, normal curing for a minimum 28 days and 4 hour soak conditioning.

Source: Austroads 2006b

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6.2 Application of Stabilisation It is unlikely that traditional subgrade stabilisation would be linked to unsealed road construction unless it formed part of a staged construction approach in which the road was intended to be sealed in the short term.

Stabilisation of unsealed road wearing surfaces is generally limited to granular stabilisation. However, modified stabilisation (particularly lime and chemical binders) may be used to enhance surface wear characteristics, slow down the rate of deterioration – mainly manifested as the generation of dust and loose, gravelly surfaces which may lead to potholes and corrugations – and reduce subsequent asset management costs, e.g. decreasing the number of patrol grading interventions and wearing course replacement (re-sheeting).

The possible use of stabilisation for improving wearing course attributes cannot be assessed quantitatively in a laboratory. However, there are some simple tests for binder suitability and these are presented in this section of the guide. Ideally, laboratory indicators should be supported by effective field trials, bearing in mind that the realisation of any cost benefit demonstrated by the laboratory result can be reduced as traffic volumes increase. A process for these evaluations is provided in Section 6.9.

Bound stabilisation techniques have generally been associated with specific unsealed sites such as floodways; however, recent use of lime stabilisation for unsealed roads has led to the successful production of bound pavement materials.

6.3 Granular Stabilisation by Blending Materials Granular stabilisation by blending materials involves:

mixing of materials from various parts of a deposit at the source of supply

mixing of selected, imported material with in situ materials

mixing two or more selected imported natural gravels, soils and/or quarry products on site or in a mixing plant.

Some typical applications of granular stabilisation are:

correction of grading generally associated with gap graded or high fines-content gravels

correction of grading and increasing plasticity of dune or river-deposited sands which are often single sized

correction of grading and/or plasticity in crushed products, quarry wastes and environmentally acceptable industrial by-products

decrease in particle breakdown of soft aggregate by the addition of harder aggregate.

Generally, granular stabilisation is adopted to align with, as far as is possible, the classification properties of an unbound granular material defined in standard road authority specifications.

6.3.1 Granular Mix Design

Granular stabilisation is adopted when it is necessary to change the intrinsic characteristics of the existing material to suit its intended purpose or to meet a particular specification. Some examples of the application of granular stabilisation are:

fine sand added to crushed rock in a pugmill, when the PI of the crushed rock material exceeds specification

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coarse aggregate added in situ to a fine pavement material for the purposes of in situ stabilisation

harder rock may be quarried and added to soft rock to meet hardness-abrasion specifications.

The mix design, in terms of grading, can be determined using simple proportion calculations of the constituent materials passing respective sieves:

((A% x Apass)/100) + ((B% x Bpass)/100) 1

where A% = percentage of material A being added

Apass = percentage of material A passing allocated sieve

B% = percentage of material B being added

Bpass = percentage of material B passing allocated sieve.

A worked example is shown in Figure 6.1, in which 70% of material ‘A’ (coarse product) is combined with 30% of material ‘B’ (fine product) to achieve a combination grading to meet a typical basecourse specification. Simple spreadsheets can be developed to perform these analyses as shown in Table 6.2.

0.000

10.000

20.000

30.000

40.000

50.000

60.000

70.000

80.000

90.000

100.000

0.010 0.100 1.000 10.000 100.000

Seive Size mm

Per

cen

t P

assi

ng

MATERIAL A

MATERIAL B

COMBINATION 70% A + 30% B

Figure 6.1: Example combination particle size analysis

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Table 6.2: Example calculation – blending two materials

Sieve size (mm) and per cent finer by mass

Material type Mix proportions

(%) 0.075 0.300 1.18 2.36 4.75 9.5 19.0 26.5

Grading of material A 70 8.0 14.0 27.0 35.0 47.0 74.0 99.0 100.0

Grading of material B 30 12.0 27.0 58.0 86.0 100.0 100.0 100.0 100.0

Combination 70/30 9.2 17.9 36.3 50.3 62.9 81.8 99.3 100.0

6.4 Stabilisation Using Chemical Binders Many products have been tried and evaluated as chemical binders. Some have been proved ineffective while others such as petroleum products, if used excessively, may have adverse environmental effects.

Chemical stabilisation binders act as surface stabilisers providing stability to otherwise unstable surface materials. The benefits of chemical stabilisation of unsealed wearing courses are:

prevention of particles becoming airborne

resistance to traffic wear

retention in pavement, i.e. not lost through evaporation or leaching

resistance to ageing

environmental compatibility

easily applied with common road maintenance equipment

workable and responsive to maintenance

cost competitive.

The primary function of chemical stabilisation is to bind the fine fractions such that they hold the aggregate fractions in place for a longer period of time. This is enhanced by the binder providing bonding and waterproofing of the fines to maintain the dry strength of the fine material.

6.4.1 Types of Chemical Stabilisation Binders

The categories of the mainstream chemical binders used in unsealed roads, and their reaction with subgrade soils and pavement materials, may be categorised as follows:

synthetic polymers

natural polymers

ionic compounds

salts.

Synthetic polymers may be grouped into water soluble and water insoluble. Most synthetic polymers in Australia and New Zealand are sold in a dry powdered format (commonly termed DPP, i.e. dry powder polymers).

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Insoluble Dry Powdered Synthetic Polymers

A water insoluble dry powdered synthetic polymer is a manufactured material that is thermally bound to a very fine carrier such as fly ash. Typically it is classified as a stabilising binder rather than a dust suppressant. The fine powdered product, when mixed with hydrated lime, has the effect of flocculating and coating clay particles within the pavement material. The fly ash, which is encapsulated by the polymer, is effectively inert and does not react chemically in the stabilisation process. Its only function is to facilitate the distribution of the polymer throughout the pavement material. This polymer is used only in the powdered format and remains in a powder form during the pavement material mixing process.

Figure 6.2 illustrates the action of an insoluble dry powdered synthetic polymer (IDPSP) coated with a fly ash carrier surrounding soil particles to induce lower permeability and hence retard the loss of strength with wetting.

Three IDPSP blends are commercially available and spread at a rate typically 1% to 2% by dry mass of pavement material:

a synthetic polymer thermally bonded to a fine powder carrier (i.e. fly ash)

a blend of 2:1 synthetic polymer-coated fly ash/ hydrated lime for medium plasticity materials (PI < 12)

a blend of 1:1 synthetic polymer-coated fly ash/ hydrated lime for higher plasticity materials (12 < PI < 20).

Source: Polymix Industries

Figure 6.2: Schematic of insoluble polymer encapsulating soil particles

Synthetic Soluble Polymers

These products are manufactured in granulated or liquid form and added to the compaction water to form the polymer chain which is an acrylimide or urethane copolymer. They encapsulate soil particles with a thin film of polymer and, upon drying, bonding and water insolubility is achieved. Figure 6.3 illustrates an acrylimide copolymer coating soil particles to induce bonding and low permeability and hence retard the loss of strength when the moisture content is greater than OMC.

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Source: Biocentral Laboratories

Figure 6.3: Electron micrograph of acrylimide copolymer coating soil particles

Natural Polymers

These products include tall oil pitch, sulphonated lignin and di-limonene which bind fine particles to interlock with larger aggregates. In addition, they often have surfactant properties enhancing compaction by dilation of fine material when compacted with a vibrating roller. Their success is dependent upon both plasticity and particle size distribution. Cement or lime can be added as a secondary binder for increased stiffness.

These products are mostly obtained as resin by-products from the pulping industry. They are often highly acidic in addition to remaining soluble and subject to leaching over time. Their use should be strictly supervised in terms of worksite safety. Due consideration should also be taken with respect to any environmental impact associated with leaching.

Ionic Compounds

These products are generally produced by the petroleum industry. They produce an ionising action in water which induces cation (+ ions, e.g. Ca++, Na+, K+, Mg++, H+) exchange at the surface of negatively-charged clay particles. By the process of ionic exchange, water that would normally be electrostatically bound to the clay particles is replaced by ions, allowing much of this water to be expelled as free water. Other processes occur including coagulation and flocculation of clay particles after compaction and some cementing action through formation of insoluble salts.

Salts

The most commonly used salt is water-attracting (hydroscopic) magnesium chloride; other salts include sodium chloride and calcium chloride. They require moisture (humidity) to be effective. They also require frequent re-application following rainfall. The consideration of salt leaching effects on the roadside environment must again be considered.

Of the chlorides used as a chemical binder, calcium, sodium and magnesium are used, with calcium and magnesium being deliquescent substances and sodium hygroscopic. The deliquescent substances absorb moisture from the atmosphere and liquefy. Hygroscopic substances, on the other hand, depend on exposed surfaces to absorb moisture. Salts such as those mentioned above control dust by keeping road surfaces damp, but have little or no cementing action. Sodium chloride is of little value in arid regions as it absorbs moisture at high humidity (e.g. 70%). Likewise, calcium and magnesium chlorides cease to absorb moisture at humidity levels below 30-40%.

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Roads treated with calcium chloride should only be graded after rainfall, and then only lightly from the edges to the centre, then reversing the operation feathering the material to the road edge. Limiting the sections to be treated will enable compaction before the surface dries, allowing bonding of the surface. Maintenance of the crown is essential with all treatments to ensure adequate drainage.

6.4.2 Applications

The main applications of chemicals in stabilisation are either as compaction aids and stabilisation binders which are mixed into a pavement layer or surface treatments for dust suppression, i.e.

chemical binders used in stabilisation:

— synthetic polymers

— natural polymers

— ionic compounds

chemical binders used to improve compaction:

— wetting agents, soaps

— synthetic polymer

— natural polymers

chemical binders used for dust suppression:

— wetting agents, soaps

— hygroscopic salts (e.g. calcium, magnesium or sodium chloride)

— natural polymers (e.g. ligno-sulphonate, molasses, tannin extracts)

— synthetic polymer emulsions (e.g. polyvinyl acetate (PVA), polyvinyl chlorate (PVC), polyacrylamide copolymers (PAM)

— modified waxes

— petroleum resins.

A study on dust control techniques, including a performance evaluation of numerous chemical dust suppressants (Foley, Cropley and Giummarra 1996), concluded that dust control methods available fell into three main categories:

good construction and maintenance practice

use of mechanical stabilisation to form a good wearing course that forms a hard surface crust

use of chemical binders as an adjunct (not replacement) to the above methods.

The sequence of remedies should follow the order given above, with possibly all methods being used to reduce dust emissions to a satisfactory level. It is considered of little value to use a chemical dust suppressant if some of the basic roads’ building requirements are not first addressed.

Short of sealing a road, there are no known ways to eliminate dust emissions effectively on a long term basis by using a single process or just one application of a chemical binder (Foley et al. 1996). However, on a life cycle basis, they can lead to lower maintenance costs through less frequent patrol grading and longer sheeting life.

Benefits from chemical stabilisation include extended periods between resurfacing, lower levels of surface roughness and hence vehicle operating costs, a reduction in accidents, higher quality primary produce and an improved amenity for nearby residents.

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Prior to using a chemical binder, unstable areas and poorly-graded material should be removed and replaced with selected material at optimum moisture content. Adequate drainage is the single most important characteristic for long-term results because it ensures the subgrade does not become saturated and therefore weakened. Surface gravel should be added and a proper crown formed to facilitate surface water runoff.

6.4.3 Product Selection and Mix Design

The selection of the type of chemical binder should be made bearing in mind the quantity of fines in the surface material or the subgrade (if there is no surfacing structure), climatic conditions and traffic volumes and construction logistics (e.g. transportation of stabilisation binder).

The consideration of proprietary chemical binders is generally based on the determination of their suitability to the parent material rather than the determination of the required application rates. Basic information is generally available from product literature together with field examples. In some cases quantitative measurement of performance or attribute improvement is available.

Chemical binders are generally separated into either dust palliatives or stabilisers and the following performance properties need to be considered:

resistance to abrasion (effect of traffic and wind on treated surfaces)

resistance to erosion

resistance to leaching

increased shear strength (all weather trafficability)

long-term durability.

The large variety of proprietary products available and classified as chemical or polymer binders, coupled with varying degrees of quality performance data, make them less definitive in their selection compared to cement, cementitious, lime or bituminous binders.

It is suggested in Part 4D of the Guide to Pavement Technology – Stabilised Materials (Austroads 2006b) that a simple capillary rise or vertical saturation test is the most appropriate (and economical) way to evaluate the suitability of a material in the laboratory. These two tests are conducted on material screened on a 2.36 mm sieve since the chemical binder is associated with the fine fractions.

Figure 6.4 shows the vertical saturation test in which a compacted specimen is prepared with and without binder, allowed to cure and dry and then subjected to saturation from dripping. The annular mass is used to induce collapse. As can be seen, the use of a binder in this particular case has shown that it could be of some value for field trialling or adoption.

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Source: ARRB Group

Figure 6.4: Vertical saturation test

6.5 Stabilisation with Lime Lime stabilisation of unsealed roads located in dry to moderate climatic conditions of Australia has been successful in increasing the strength of the pavement material in both dry and wet conditions, reduce dust generation and lower the frequency of resheeting to about five to 10 years. The application rate of lime is at least that quantity required to reach the lime demand criterion such that long term stabilisation can take place. Additional lime has been used at intersections to improve the durability of the surface from turning traffic conditions.

In sections of weak subgrade the existing formation material has been in situ stabilised with lime to provide longer performance to the pavement material of unsealed roads.

6.6 Stabilisation with Cementitious Binders In addition to lime stabilisation of unsealed roads, cementitious binders have been successfully used on unsealed low volume roads and as localised treatments, such as floodways, bends, intersections, etc. Circumstances where the use of cementitious binders may be considered include:

improving the subgrade strength to significantly reduce pavement depth or where saturated subgrades are encountered

modifying poor materials to make them suitable as a pavement layer

enhancing wear resistance and/or reduce dust emissions from the wearing course.

More comprehensive detail on stabilisation using these types of binders may be found in Part 4D of the Guide to Pavement Technology (Austroads 2006b).

6.7 Stabilisation with Powder Binders Stabilisation of unsealed roads with powder binders is generally limited to the use of lime or cement as localised treatments such as floodways, bends, intersections, etc. However, in some circumstances, the use of cement or lime may be considered where:

improving the subgrade strength may significantly reduce pavement depth or where saturated subgrades are encountered

poor materials are modified to become a suitable pavement layer

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wear resistance can be enhanced or dust emissions from the wearing course reduced.

More comprehensive detail on stabilisation using these types of binders may be found in Part 4D of the Guide to Pavement Technology (Austroads 2006b).

6.8 Methods of Applying Stabilisation Binders in the Field 6.8.1 Powder Binders

Powder binders require spreading on the road surface with a purpose-built spreader where the application rate can be closely monitored and controlled (Figure 6.5).

Source: AustStab

Figure 6.5: Purpose-built stabilisation binder spreader

Uncontrolled applications may be undertaken on short lengths (e.g. floodways) with 20 kg bags laid in a grid pattern and spread by rake. In this situation workers must be equipped with personal protective equipment.

In all cases, thorough mixing of powder binders can only be achieved using a purpose-built road recycling machine. The use of grader mixing will result in poor distribution of the stabilisation binder in addition to requiring mixing times which may exceed the hydration time for cementitious binders.

6.8.2 Liquid Binders

Liquid binders are best added by pumping the mixture into the spray bar contained in the mixing chamber. A low quality and uncontrolled approach is to spray the mixture to the road bed via a water truck. They can be pumped directly into the water truck or a venturi system adopted which is attached to the water filling system however there is no method to ensure that the binder is well displaced within the water truck (Figure 6.6).

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Source: ARRB Group

Figure 6.6: Application of liquid stabilisation binder with water truck

In the case of powder or granulated binders (e.g. polyacrylamides) that are added to the water truck, a recirculating system or patented eductor mixing system is required (Figure 6.7).

Source: ARRB Group

Figure 6.7: Adding granulated polymer using patented eductor

6.8.3 Methods of Mixing

Purpose-Built Recyclers

In all cases, thorough mixing of binders into the road material can only be achieved using a purpose-built road recycling machine (Figure 6.8). The use of grader mixing will result in poor distribution of the stabilisation binder in addition to requiring mixing times that may exceed the hydration time for cementitious binders. In addition, the application of water through the mixing chamber can greatly improve the compaction of the stabilised material.

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Source: ARRB Group

Figure 6.8: Stabilisation binder mixing with purpose-built recycler

6.9 Logistical Selection of Stabilisation Binders for Construction In addition to laboratory mix design considerations, the selection of a particular binder needs to be considered in terms of the following:

The quantity of stabilisation binder required for logistical transportation to the site and to meet the construction demands.

The cost of the binder, including transportation to the site and on-site handling, e.g. bulker bags or tanker transfer to the spreader. Typical (ex-bin) costs of liquid chemical binders range between $8,000 and $12,000 per kilometre and $4,000 (cement and lime) to $50,000 (some polymers) with 2% by mass addition of powder binders.

Any additional plant required for powder binders, e.g. a mechanical spreader and mixer.

Any potential reduction in compaction moisture content that can realise a saving in water carting costs; waiting for water to be delivered to a site can be critical during construction

OH&S issues associated with some binders affecting the health of workers (e.g. dust) and skin damage associated with quicklime and sulphonated lignin products.

Chemical residues left in water tankers including those (mostly acidic) which preclude the tanker from being used for domestic water supply in construction camps and those which accelerate rusting of construction plant.

6.10 Technical Evaluation of Stabilisation Binder Performance 6.10.1 Laboratory Evaluations

The process for establishing the suitability and quantity of stabilisation binder in the laboratory is as follows:

1. Identify local materials proposed for construction and consider blending materials to match, as closely as possible, the suggested PSD provided in Table 3.5.

2. Review binder product literature, placing particular emphasis on the results of field trials (particularly independent trials) and quantitative stabilised pavement data.

3. Prepare test samples at the binder content recommended in the manufacturer’s specification.

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4. If the product is designed to provide water-proofing properties, binder suitability and content confirmation by capillary rise, vertical saturation or permeability testing is recommended.

5. If the product is designed to provide increased strength characteristics, binder suitability and content confirmation using CBR or UCS testing is recommended.

6. If the product is designed to provide improved compaction characteristics, binder suitability and content confirmation by laboratory compaction testing is recommended.

7. Depending on the outcomes of the laboratory testing, adjust the binder content as appropriate if the binder appears suitable.

8. If insufficient field performance data is available, undertake a field trial, ensuring that an untreated (or proven treatment alternative) section is included as a base measure or ‘control’. Alternatively, if the laboratory testing suggests that the product may be suitable, adopt it for the project and monitor performance for future application.

9. Monitor in-service performance over the length of the treatment life and document changes to all sections in the trial.

6.10.2 Field Trials

Many case histories exist but it is common to find that many trials lack a design method which would isolate and define the effect of the product. A more definitive assessment of the effectiveness of a product or process should take into account materials safety data sheets associated with the proposed binders, material type, construction achievement, climate and nature of traffic and comparisons with a base product/process (generally traditional practice).

Control sections

A full scale road trial should incorporate at least one control section, which is constructed at the same time as the experimental sections. The control sections must be identical in all respects to the experimental sections, except that no additive is used. The difference in performance between the experimental and control sections is then used to determine the effectiveness of the additive.

A control section also helps eliminate any advantages resulting from extra supervision provided during the construction of the experimental sections. Care needs to be taken to ensure that construction follows recommended practice as normal practice may differ from that required for a specific binder. In addition, care needs to be taken to ensure that any improvement in the performance of a trial section is solely due to the binder and not different construction or increased compaction applied due to more intense surveillance. The performance of the control section, using the same materials (but with no additive) and laid under the same conditions, will indicate whether the observed performance of the experimental sections is due to the additive, or other causes.

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7 UNSEALED SURFACE WEARING CHARACTERISTICS

7.1 Introduction This section describes the various wearing and environmental factors influencing the quality of the riding surface of an unsealed road. For aspects associated with maintenance and construction of unsealed roads, the reader is referred to the ARRB Unsealed Roads Manual – guidelines to good practice, 3rd Edition (Giummarra, Ed, in press).

Unsealed surface wear is a characteristic which is dependent upon the different types of surfacing materials, traffic volumes and axle configurations, climatic conditions, quality of construction and frequency of maintenance applied.

Surface defects are commonly considered to represent deterioration in unsealed road pavements. They often control maintenance intervention strategies (e.g. patrol grading) in association with considerations on the importance of the road.

Deterioration models have been developed based upon either gravel loss (sheeting life) or surface roughness (rideability) which predicts both sheeting life and maintenance intervention for application in life cycle analyses.

7.2 Types of Surface Wear Wearing of the surface can be:

traffic induced:

— dusty surface when trafficked, resulting in loss of fines and the development of coarse texture

— loose aggregate pulled out of the surface due to loss/lack of fine material binder

— loss of crossfall (crown elevation) through loss of fines and aggregate

— rough corrugated surfaces where very sandy surfaces are encountered

rain induced:

— potholes formed from permeable surfaces and poor crossfall, allowing water to pond

— lateral erosion on crossfalls

— total loss of trafficability during floods, particularly fine grained surfaces (silts and clays)

— surface gouging on soft surfaces during/after rainstorms.

The ARRB Unsealed Roads Manual (Giummarra, Ed, in press) provides greater detail with respect to unsealed surface wear, defects and suggested treatments for repair and avoidance.

7.2.1 Loss of Fine Material (Dust)

The loss of fine material is the first sign of the wearing of an unsealed road surface. It is manifest as dust generation and aggregate exposure, resulting in coarse surface texture, roughness and noise.

Dust is caused both by the loss of fine particles (finer than 0.425 mm) from the road surface arising from the loosening of the pavement materials, and disturbance to the wearing course caused by the action of traffic and climatic conditions.

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A loss of fines leads to an increase in the permeability of the surface, resulting in early pavement deterioration and accelerating the need for re-surfacing. Loss of fines also exposes a coarser textured surface, leading to higher levels of irregularities and hence increases in vehicle operating costs. It also contributes to road safety issues. A typical advisory sign for dust hazard is shown in Figure 7.1.

Source: ARRB Group

Figure 7.1: Advisory sign for dust hazard

It is important to note that any dust suppression treatment on an unsealed road surface is not permanent but forms part of an overall road management strategy which may imply regular applications of the palliative (i.e. water or water plus an additive).

The US Department of Agriculture (1999) provides guidance on the use of dust palliatives.

Quantitative measurement of dust generation can be made using specific detection apparatus developed by the US Army Research and Development Centre (Rushing 2006) (Figure 7.2).

Source: Rushing (2006)

Figure 7.2: Mobile and static dust monitoring apparatus

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The Colorado State University developed the ‘Dustometer’ which can be described as a moving dust sampler that provides a real-time quantitative dust emission measurement for a section of a road. Its dust measurements are precise, reproducible, and easily obtained (Sanders and Addo 2000). It provides a uniform procedure for gathering and comparing data from many test sections; many data points can be generated within a short period of time.

The device consists primarily of a fabricated metal box designed to hold a 10 x 8 in (approx. 250 x 200 mm) glass fibre paper which is mounted to the bumper of a pick-up truck behind the driver's side rear tyre, an electric power generator, a high-volume vacuum pump, and a flexible plastic tube connecting the suction pump to the filter box. The fabricated filter box has a 12 x 12 in (approx. 300 x 300 mm) opening that is covered with a 450 m mesh sieve screen that faces the tyre. The screen prevents any non-dust particles from being drawn onto the filter paper during dust measurement. The filter paper is supported near the bottom of the fabricated box by a sieve mesh. A schematic diagram of the ‘Dustometer’ is shown in Figure 7.3.

Source: Sanders and Addo (2000)

Figure 7.3: Schematic diagram of Colorado State University Dustometer

Surface texture

Surface texture is developed by the gradual loss of fines on the surface exposing the aggregate which, depending on the strength of the fines (binder), can result in the aggregate producing a loose surface (Figure 7.4).

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Source: ARRB Group

Figure 7.4: Loss of fines increasing surface texture

Texture can be measured using the sand patch method (ASTM E965, 2006) or the automated laser profilometer.

During construction, it is common to reduce the rate at which fine material is lost by slurrying the surface with water (or water plus an additive) (Figure 7.5) such that sufficient fines surround the aggregate to hold it in place.

Source: ARRB Group

Figure 7.5: Slurrying unsealed surface

The surface can be restored periodically using routine patrol grading to remove loose material to the side windrows of the pavement. However, at some stage the loss of fine material is such that the surface becomes very coarse (Figure 7.6) and ‘boney’.

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Source: ARRB Group

Figure 7.6: Loss of fine material leaving coarse gravelly surface

7.2.2 Loose Gravel

The generation of loose gravel under traffic, termed ravelling, may be a significant safety and economic problem. Loose gravel may be distributed over the full width of the road but is commonly concentrated in windrows between the wheelpaths (Figure 7.7). The problems caused relate to safety hazards, damage to vehicles and windscreens, increased fuel consumption and lack of adequate lateral drainage.

Source: ARRB Group

Figure 7.7: Loose material between wheelpaths (note centre overlap from trafficking in both directions)

The measurement of the rate of deterioration of loose surface material has been undertaken in a number of unsealed road studies (e.g. Andrews 2000). This rudimentary test involves the removal of the loose material within a square metre of pavement and weighing it (Figure 7.8). The loss of material over time allows surfaces to be rated as shown in Figure 7.8.

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0

2

4

6

0 200 400 600 800 1000 1200

D ays

T o tal D ust Gravel

R o ugh

Smo o th

Serviceable

Surf ace g raded f o r f irst t ime af t er 16 mont hs service

Surf ace graded af t er rain

Source: ARRB Group

Figure 7.8: Measurement of loose material on pavement surface

7.2.3 Corrugations

Corrugations are mostly formed through loose surface material being displaced as a result of tyre action coupled with the mass and speed of the vehicle. Loose surface material arranges itself into parallel ridges which lie at right-angles to the direction of traffic. Spacing (wavelength) can vary from 500 mm to 1 m and depths can range up to 150 mm (Figure 7.9). Any irregularity in the surface can initiate the process which then develops at a rate dependent upon the traffic, speed and tyre pressure.

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Source: OECD (1987)

Figure 7.9: Corrugation formation in dry climates

Granular materials with particle sizes greater than 5 mm, low plasticity and limited fines, or materials which have lost fines due to traffic action, are susceptible to corrugations (Figure 7.10). In dry climates only the material that forms the ridges is affected, with the underlying material remaining in place.

Source: Giummarra (in press) Source: ARRB Group

Figure 7.10: Corrugations in gravel surface (left) and sandy surface (right)

In wet climates corrugations generally develop during the dry season. However, if the pavement and basecourse become soft enough due to saturation, deformation through the full pavement structure can occur as shown in Figure 7.11.

The absence of a tight surface, combined with coarse sandy material, if present in high proportions, can lead to the rapid formation of corrugations.

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Source: OECD (1987)

Figure 7.11: Corrugation formation in wet climates

7.2.4 Potholes

Potholes play a significant role in the development of ride quality, or roughness, of unsealed roads. They can cause substantial damage to vehicles if allowed to develop and increase in size. The effect of potholes on vehicles depends on both the depth and diameter of the pothole. Potholes which affect vehicles the most are between 250-1500 mm in diameter with a depth of more than 50-75 mm.

Roads particularly susceptible to potholing are those with flatter grades and crossfalls, particularly at bridge approaches, alignment changes from ‘left to right’, superelevation at ‘S’ bends, and intersections where water can lie on the surface, particularly in wheelpaths. Pothole occurrence is rare on gravel roads with correct crossfall and superelevation. The development of potholes is triggered by stripping of the surface material and the infiltration of water. Solids in suspension are carried away by wheel action on the surface and, as water penetrates the pavement, the action continues, forming a hole in the pavement (Figure 7.12).

Source: Giummarra (in press)

Figure 7.12: Potholes on flat crossfall

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7.2.5 Dry Rutting in Wheelpaths

Rutting on unsealed roads in dry environments is mostly due to the loss of material in wheelpaths caused by trafficking (Figure 7.13). However, if insufficient pavement thickness exists over a soft subgrade rutting (refer Figure 4.3) can be due to vertical deformation under traffic or, in the case of a weak wearing course or basecourse, shear failure (shoving) of the layer.

Source: ARRB Group

Figure 7.13: Dry rutting in wheelpath

Dry season rutting occurs in sand and gravels that have low plasticity such that loose material is displaced sideways and traffic continues to travel in the same wheelpath.

7.2.6 Surface Gouging

Surface gouging (Figure 7.14) occurs in those materials where the strength is sensitive to water ingress such as wearing course materials with high clay and/or silt contents. Surfaces become instantly slippery and, with continued saturation (or inundation), this is the greatest cause of road closures and inaccessibility issues associated with the strategic function of the road.

Source: ARRB Group

Figure 7.14: Surface gouging

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7.2.7 Surface Scour

Scour is the loss of surface material caused by the flow of water along and/or over the road. It is related to a lack of compaction, excessive longitudinal grade and the build-up of debris on shoulders preventing surface water from flowing off the pavement (Figure 7.15).

Both transverse and longitudinal scouring can occur. Transverse scouring commences at the edge of the shoulder or on areas where the level of compaction is lower and works towards the road pavement (Figure 7.16). Alternatively, a lack of adequate shoulder slope may lead to water standing on the road and eventually finding an escape route. Plant growth on shoulders, and the consequent entrapment of debris and earth, prevents water draining from the pavement. An area where the prevailing longitudinal grade encourages water to flow along the pavement in preference to the direction of the crossfall gives rise to longitudinal scouring (Figure 7.17).

Longitudinal scouring is more likely to occur on areas having steep vertical grades.

Source: ARRB Group

Figure 7.15: Longitudinal scour on steep gradient

Scouring of the surface not only creates adverse driving conditions but also leads to further deterioration of the pavement through exposure to the environment. Scouring can be pronounced when combined with material susceptible to rutting. The ability of the surface material to resist scour depends on the shear strength of the material subject to the water flow.

Pavements with high fines contents and small aggregates are more inclined to scour than those consisting of a well-graded mix containing crushed stone 19 mm in size or larger.

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Source: Giummarra (in press)

Figure 7.16: Transverse scouring on horizontal curve

Source: Giummarra (in press)

Figure 7.17: Longitudinal scouring between wheelpaths

7.2.8 Ice Formation on Surface

The presence of ice on the surface results in a reduction in the coefficient of friction between the tyre and the surface to almost zero, leading to unpredictable vehicle movements and very hazardous driving conditions (Figure 7.18). Surfaces subjected to ice or frost are either closed or treated with grit or chemicals such as calcium or sodium chloride.

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Source: Giummarra (in press)

Figure 7.18: Snow and ice formation

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8 UNSEALED ROAD SURFACE MANAGEMENT

8.1 Introduction The management of unsealed roads surfacings is predominantly undertaken based on local knowledge of the performance of specific pavements within a network. Surface condition is generally maintained by routine patrol grading initiated (based on local knowledge) by known performance or in response to complaints by road users. Resheeting operations involve replacing the wearing course when it has worn away in a similar manner to a granular overlay on a pavement.

Given that these resheeting operations are normally based on local knowledge, or complaints by road users, it is difficult to develop formal methodologies for the management of unsealed roads surfacings that could be applied at the network level. However, given the large costs associated with resheeting unsealed pavements, greater emphasis is now being directed towards the development of network-level maintenance intervention strategies, including surface deterioration models which more accurately predict surface life.

8.2 Surface Maintenance 8.2.1 Patrol Grading

Patrol grading normally consists of grading the surface to side windrows to improve the smoothness of the surface Figure 8.1. However, heavier grading (i.e. more material moved) is adopted where the road requires reshaping, generally after periods of heavy traffic (e.g. de-stocking stations or mine hauls) or severe surface damage caused during wet weather trafficking. In these circumstances the pavement surface is typified by high quantities of loose material, rutting and loss of crossfall and, after rainfall, gouging and potholes.

Source: ARRB Group

Figure 8.1: Patrol grading

In these operations, the material is generally shallow-graded to side windrows and, when the surface becomes ‘boney’, i.e. coarse texture, fine material from the windrow is brought back over the surface. However, when undertaking this operation, care should be taken not to produce a thin skin of material over the old surface as this will delaminate rapidly, leading to the formation of potholes.

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In addition to grading, the performance of the surface can be significantly improved by compacting the surface after grading. Tow-behind rollers are commonly used to compact surfaces which have been disturbed by grading operations. They can be used behind the grader or as a separate operation using a small tractor. Types of tow-behind rollers include static and vibratory rollers, steel drum and rubber-tyred rollers, and combination rollers (Figure 8.2).

The level of compaction achieved using tow-behind rollers will not be as high as the level provided by a separate roller.

Source: Earthco Projects Pty Ltd

Figure 8.2: Tow-behind steel drum roller and multi-tyred roller

In addition to normal compaction, it is also quite common to slurry the surface (Figure 8.3) which, under the pore pressure developed beneath the static roller, brings fine material to the surface. The fine material assists in retaining the aggregate fractions in place through cohesion, particularly if it has medium plasticity. This operation can also be associated with the incorporation of liquid stabilisation binders. However, care needs to be taken when slurrying not to produce a highly slippery surface (often achieved when some liquid stabilisation binders with high surfactant properties are used). Appropriate warning signs must be placed on new work until the surface has thoroughly dried.

Figure 8.4 compares a typical surface subject to wet compaction and slurrying (left) and dry compaction (right).

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Source: ARRB Group

Figure 8.3: Surface slurrying during compaction

Source: ARRB Group

Figure 8.4: Wet compaction and slurrying (left) and dry compaction (right)

8.2.2 Reshaping and Shallow Stabilisation

Reshaping, involving the scarification of the road surface and remixing of the aggregate base, can yield a proper blending of fines and aggregates and the restoration of an appropriate crowned road surface. Scarifying operations can also be adopted in thin stabilisation applications where liquid binders are used. A typical surface after scarifier grading is shown in Figure 8.5.

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Source: Giummarra (in press) Source: Earthco Projects Pty

Figure 8.5: Surface after scarifier grading

8.3 Resheeting (Wearing Course Replacement) Gravel loss and subsequent replacement by re-sheeting is the most significant factor affecting the life cycle operating costs of an unsealed road pavement. Typically a 150 mm thick unsealed wearing course will be lost within 8 to 12 years, after which a new wearing course will be required.

The loss of wearing course material on unsealed roads results from:

traffic abrasion and loss of fine binding material

degradation of stone due to weathering and polishing

climatic conditions, i.e. wind and rain introducing scouring and erosion

patrol grading loose material to windrows and over-cutting the surface

pavement material selection.

8.3.1 Measuring and Estimating Gravel Loss

The ability to correctly estimate gravel loss is very useful to a manager scheduling resheeting operations because it helps identify where resheeting is required and the amount of material required. However, there is currently little information available regarding actual gravel loss, how much gravel is on the road and therefore what gravel is to be added. It would seem that many practitioners wait for the subgrade to show through before resheeting, which is far too late.

Gravel loss can be estimated by:

monitoring core levels of gravel depth over time

taking spot levels on various representative sections of roads and measuring annual wear loss

measuring the rate of loose material generated between wheelpaths (Andrews 2001)

applying a formula, calibrated to local conditions, to estimate loss

using technology based on ground penetrating radar to measure existing gravel depth

differentiating between the materials used in the base and wearing course.

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Ground penetrating radar (GPR)

An innovative approach to estimating gravel loss is the use of GPR technology. The technology uses a pulse of energy fired into the road surface and the time delay of its reflection to calculate the distance to the object and thereby the thickness of different layers in a pavement. GPR equipment mounted on a vehicle can travel at moderate speed. GPR antennas can come in various forms, including above, and close to, the surface. A horn-based antenna, which is an above-surface type, is shown in Figure 8.6.

Source: Giummarra (in press)

Figure 8.6: Ground penetration radar (GPR) with horn antenna

Trials on the suitability of different GPR systems, on both sealed and unsealed roads, have provided favourable results (Giummarra 1998). However, care should be taken when using GPR equipment to ensure that the gravel and subgrade dielectric properties are suitable. An initial test section should be used to ascertain the suitability of this equipment to local pavement conditions.

8.3.2 Predicting Gravel Loss

International studies of the performance of unsealed roads have led to the development of a number of models, in particular relating to World Bank projects in developing countries. These models consider the inter-relationships between construction, maintenance and vehicle operating costs. Factors considered include:

the impact of gravel loss on resheeting intervention

the impact of surface looseness on vehicle operating costs (VOC)

the impact of surface roughness on maintenance intervention

the impact of rut depth on maintenance and re-sheeting intervention strategies

journey time as an indicator of road condition

traffic volumes (both ways) as an indicator of pavement wear

the impact of climate on surface dust and erosion characteristics

geometry (slope and camber) as an indicator of erosion.

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In the absence of historical data to provide the most accurate determination of future gravel loss from the sheeting material along an unsealed road, various predictive formula have been developed, three of which are now discussed. Where possible, these models have been adjusted to minimise the number of parameters, example calculations are provided in Table 8.1.

Predictive Model 1: TRRL

The Transport and Road Research Laboratory (TRRL) (now TRL) model was originally based on the results of a study in Kenya and developed by Jones (1984). The model is described by the formula:

GLA = f(0.133(ADT)2/((0.133ADT2 + 50)) x (4.2 + 0.0336ADT + 504MMP2 + 1.88VC)

1

where GLA = annual gravel loss (mm/year)

ADT = average daily traffic in both directions (veh/day)

MMP = mean monthly precipitation (metres/month)

VC = gradient (%) for uniform road length

f = constant for various gravels (laterite: 1.3,quartzite:1.5, volcanic:0.96, coral:1.5, sandstone:1.4, calcretes: 2.0-4.5)

Predictive Model 2: HDM-4

The HDM-4 model, as described by Paterson (1987) and can be described as follows:

GLA = 12.63 + 0.898(MMP x G) + 3.65(KT x ADT))

2

where GLA (MLA in original formula) = predicted annual material loss (mm/year)

MMP = mean monthly precipitation (mm/month)

G = average longitudinal gradient of the road (%)

ADT = average daily traffic in both directions(veh/day)

KT = traffic-induced material whip-off coefficient.

and

KT = MAX(0, 0.022 + 0.969(KCV/57300) + 0.00342(MMP x P075) – 0.0092(MMP x PI) – 0.101(MMP)) 3

where PI = Plasticity Index

KCV = average horizontal curvature of the road (deg/km)

P075 = amount of material finer than the 0.075 mm sieve.

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Predictive Model 3: Paige-Green (1990)

This model is described by the formula:

GLA = 3.65(ADT(0.059 + 0.0027N – 0.0006P26) – 0.367N – 0.0014PF + 0.0474P26) 4

where GLA (GL in original formula) = annual gravel loss (mm) Fawcett et al. (2001)

ADT = average daily traffic in both directions

N = Weinert N-value (a climate index value)

PF = plastic factor (plastic limit x per cent passing the 0.075 mm sieve)

P26 = per cent passing the 26.5 mm sieve.

It was recommended that the particle size distribution be recalculated assuming that 100% was passing the 37.5 mm sieve and that the Weinert N-value (12 x evaporation in the hottest month(mm)/annual precipitation(mm)) be limited to a maximum value of 11 (Jones, Sadzik and Wolmarans 2001).

Table 8.1: Comparative rates of annual gravel loss

Location: Unsealed Road through Flinders Ranges, South Australia

Predictive Model 1: TRRL Predictive Model 2: HDM-III Predictive Model 3: Paige-Green

Input Parameters:

Material f = 1.4

PI = 20, P075 = 22

P26 = 95, P075 = 23, PL = 15, PF = 345

Traffic ADT = 92 vehicles per day

ADT = 92 vehicles per day

ADT = 92 vehicles per day

Rainfall MMP = 0.026 metres/month

MMP = 0.026 metres/month N = 11

Alignment VC = 0 G = 0, KCV = 0, KT = 0.017

Annual Gravel Loss GLA = 10 mm GLA = 18 mm GLA = 11 mm

It was noted that the gravel loss along the unsealed road was believed to be between 7 mm and 14 mm per year.

8.4 Unsealed Road Condition Monitoring The benefits of efficient unsealed road network management systems are as follows:

They provide an indication of the current level of service provided by the network and the associated costs of maintaining current service levels.

They allow estimates to be made of the costs associated with increased levels of service to meet socio-economic and environmental demands on the network.

Patrol grading maintenance interventions can be planned so that they are deployed where and when required to meet the functionality of a particular road.

They provide an indication of the life of the wearing course (sheeting) in order to forward plan re-sheeting schedules which, because of high initial capital outlay, represent the highest unit costs associated with road operating costs.

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They provide data identifying high operating-cost roads that may be candidates for upgrading, i.e. improved unsealed wearing course material, stabilisation applications or bituminous sealing.

They provide a rational platform upon which planning for funding submissions can be made.

8.5 Visual Pavement Condition Rating Systems There is no commonly adopted pavement condition rating system in Australia and New Zealand for unsealed roads although there are a number of commercial products available from various sources. The easiest and most common system is based upon visual assessment by trained inspectors identifying the severity and extent of the particular condition attribute from which a numerical rating system is applied to establish a condition index.

Two systems (South Africa and the US) are now described.

8.5.1 South Africa

The pavement condition assessment part of the system (Jones and Paige-Green 2000) can be applied routinely to maintenance operations as a basis for:

predicting gravel loss and patrol grading frequency

prioritising maintenance actions (e.g. defects with a severity of four or five should be given immediate attention, whilst defects with a severity of three should be considered as a warning that will require attention in the near future)

monitoring improvement or deterioration in the overall road network as a result of funding fluctuations

direct comparisons of the performance of various roads

the identification of specific problems

project level investigations.

The assessment is undertaken on segments of the road network visually and numerically rated on a scale of one (very good) to five (very poor). To assist in making the rating system more uniform, Jones and Paige-Green (2000) provide example pictures of each attribute in terms of its rated category.

The inspection is made from a vehicle travelling at 40 km/h and gathers data relating to:

general performance of the road to meet road function and road user satisfaction

moisture condition at the time of assessment

wearing course thickness and quality

road profile (loss of crossfall)

drainage adequacy

ride quality (roughness (IRI))

dust (visibility and safety)

trafficability or accessibility, classified as acceptable or not

potholes – estimates of depth and extent

rutting: estimate of depth

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stoniness (texture) : a measure of texture where stone is embedded and the presence of loose stone in windrows between the wheelpaths

slipperiness or skid resistance: classified as acceptable or not

cracks: as observed in the dry clay surfaces.

8.5.2 USA

This system established an ‘unsealed road condition index’ (URCI) as a numerical indicator based on a scale of 0 to 100 as shown in Table 8.2 (Department of the Army 1995).

Table 8.2: US Army URCI scale and condition rating

0 - 10 10 - 25 25 - 40 40 - 55 55 - 70 70 - 85 85 - 100

failed very poor poor fair good very good excellent

The inspection is undertaken from a vehicle traveling at 40 km/h in sections (sample units) to determine, firstly, the density of the specific defect (per cent of section area or length) and, secondly, its severity (deduct values) based on the density and whether there is a low, medium or high impact on road function.

The defect attributes are: improper cross-section (loss of crown or flat crossfall), inadequate roadside drainage, corrugations, dust, potholes, rutting and loose aggregate.

Deduct value curves have been developed for each distress mode as shown in Figure 8.7 and Figure 8.8.

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Source: United States Department of the Army (1995, Figures C-2, C-3 & C-4)

Figure 8.7: Condition deduct values (drainage, cross-section, corrugations, dust)

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Source: United States Department of the Army (1995, Figures C-5, C-6 & C-7)

Figure 8.8: Condition deduct values (potholes, ruts, loose aggregate)

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From summing all the deduct values, the URCI is determined using Figure 8.9.

Source: United States Department of the Army (1995, Figures C-8)

Figure 8.9: US Army URCI calculation

The URCI is calculated as shown in the following example:

1. Determine the density of the defect.

2. Calculate the density as a percentage of the section (sample unit).

3. Determine the deduct values from Figure 8.7 and Figure 8.8.

4. Sum the deduct values and determine the ‘q’ value.

5. Determine the URCI from Figure 8.9 and the overall condition rating is obtained from Table 8.2.

As an example calculation of the pavement shown in Figure 8.10 follows.

Source: ARRB Group

Figure 8.10: Pavement assessment example

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A pavement inspection of a 150 m sample unit gave the following rating:

— improper cross-section – 30 m: density = 30/150 x 100 = 20; severity: low (i.e. low crossfall)

— corrugations – 80 m: density = 80/150 x 100 = 53; severity: medium

— dust – medium: deduct value = 4

— loose aggregate – 80 m: density = 80/150 x 100 = 53; severity: low

Determine the deduct values from Figure 8.7 and Figure 8.8, viz.

— improper cross-section deduct value = 14

— corrugations deduct value = 45

— dust deduct value = 4

— loose aggregate deduct value = 18

Total Deduct Value = 14 + 45 + 4 +18 = 81 and q = 3

URCI (determined from Figure 8.9) = 46 and, from Table 8.2, the pavement is rated as FAIR.

A typical assessment and condition calculation sheet is shown in Figure 8.11.

Source: United States Department of the Army (1995, Figure 3-2)

Figure 8.11: US Army unsealed road condition assessment form

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8.6 Quantitative Pavement Condition Rating Quantitative measurements of the condition of unsealed road surfaces have been developed to rate a range of attributes of the road surface by direct measurement. More recently, the collection of IRI roughness, rutting and texture data in an automated manner at highway speeds has become common in Australia and New Zealand.

Pavement roughness can be measured using a Roughometer which can be fitted to a vehicle as shown in Figure 8.12.

Source: ARRB Group

Figure 8.12: Roughometer

In addition, rutting and roughness can be determined using a laser profilometer mounted to the front of a vehicle as shown Figure 8.13.

Source: ARRB Group

Figure 8.13: Laser Profilometer

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An alternative system known as ‘Optigrade’ was developed by the Forest Engineering Research Institute of Canada originally to manage the grading maintenance of unsealed forest hauls roads. The system comprises an accelerometer and GPS hardware mounted on a haul truck routinely traveling the road, and software designed to assist managers making decisions on grading frequency.

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9 COST–BENEFIT CONSIDERATIONS

9.1 Concept Effective asset management demands that a systematic approach be taken to the whole-of-life (life-cycle) management of any infrastructure component in order that an efficient and an effective management system are provided to the users.

Road asset management strategies involve the establishment of a program of systematic monitoring of pavement condition, physical treatments (construction, maintenance and rehabilitation) applied to roads, and controls on how the roads are operated. These actions directly influence the level of service provided to the road users and, ultimately, community benefits.

Economic evaluation is an objective asset management tool used to demonstrate accountability and the effective management of road assets. Economic evaluation is used, once all the consequences have been quantified, to assist in the selection of new road investments and the physical treatments and controls to be applied to existing roads.

The adoption of cost-benefit analyses, in the form of life cycle cost models, can provide definitive information regarding the likely benefits associated with materials selection and blending or stabilisation as well as different construction options. In the past, the selection of options was based solely on the initial prime costs of construction for new works or resheeting or, in the case of maintenance, the prime cost of patrol grading. Both of these are generally poorly defined in terms of actual costs.

Criteria other than construction and maintenance costs are also often used in asset management. For example, the majority of unsealed roads exist primarily to provide access for the local community and freight movement, functions which are not incorporated in current economic evaluations. In addition, road safety is a critical consideration in the management of the road network, including unsealed roads.

In the absence of suitable data on other road operating factors applicable to the sealed road network, the life cycle methodology presented in this Guide is limited to construction and maintenance considerations.

9.2 Life Cycle Analyses for Selection of Wearing Course and Associated Maintenance Management Strategies

9.2.1 Introduction

In the context of unsealed roads, life cycle analyses can be used to evaluate any benefits gained from processes which increase sheeting life or reduce patrol grading intervention (i.e. termed ‘performance’ in this Guide). Examples could include:

the benefits of incurring additional prime costs associated with improving materials by blending materials from different locations to improve performance

the benefits of incurring additional costs through the incorporation of a chemical binder in the wearing course to improve performance

the evaluation of the location of water supplies and water reducing agents on the prime construction costs.

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9.2.2 Life Cycle Cost Analyses

Life cycle analysis is based on Net Present Worth (NPW) and Equivalent Annual Cash Flow (EACF), which are defined by the following formulae:

+=

nn)r1(

1C$NPW and

−++=

1)r1(

)r1(r NPWEACF

N

N

where $Cn = treatment cost in year ‘n’

r = discount rate of future expenditure (taken as 6%, including the net effects of inflation)

n = number of years projected into the future

N = life of the strategy.

Typical uses for life cycle analyses include:

1. Determining the operating costs of an existing pavement to assist in forward planning funding.

2. Blending materials to improve wearing course performance, increase sheeting life and reduce patrol grading. In this analysis the additional costs of mixing or bringing a second material to site is considered.

3. Adding a stabilisation binder to improve wearing course performance, increase sheeting life and reduce patrol grading. In this analysis the cost of the stabilisation binder and any ancillary equipment (recyclers and binder spreaders) are considered.

4. Determining if it is viable to seal a pavement in the event that maintenance costs are high. In this analysis the cost of maintaining and replacing the wearing course at intervals determined from gravel loss estimates against the cost of sealing (which may include the cost of providing an improved basecourse material) is considered.

A typical example analysis is shown in Table 9.1 and Figure 9.1 where the cost of maintaining a pavement with an estimated 10 year wearing course life and annual patrol grading intervention are assessed:

life cycle analysis period 20 years

initial construction cost of wearing course $25,000/km

patrol grading annually $150/km

replace wearing course every 10th year $25,000/km

discount rate 6%

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Table 9.1: Example life cycle analyses

Year Activity Sheeting cost

Stabilisation binder cost

Grading intervention

Patrol grading cost

Discount rate

Analysis period

Annual NPW $

Net present worth $

Equivalent annual cash flow $

0 Resheet $25,000 6 months $150 0 20 25150 39303 3427 1 Patrol grade $150 0.06 133

2 Patrol grade Sheeting life

$150 0.06 126

3 Patrol grade 10 years $150 0.06 119

4 Patrol grade $150 0.06 112

5 Patrol grade $150 0.06 106

6 Patrol grade $150 0.06 100

7 Patrol grade $150 0.06 94

8 Patrol grade $150 0.06 89

9 Patrol grade $150 0.06 84

10 Patrol grade $150 0.06 79

11 Resheet $25,000 $150 0.06 12499

12 Patrol grade $150 0.06 70

13 Patrol grade $150 0.06 66

14 Patrol grade $150 0.06 63

15 Patrol grade $150 0.06 59

16 Patrol grade $150 0.06 56

17 Patrol grade $150 0.06 53

18 Patrol grade $150 0.06 50

19 Patrol grade $150 0.06 47

20 Patrol grade $150 0.06 150

$150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150

$25,000 Resheet$25,000 New surface

$0

$5,000

$10,000

$15,000

$20,000

$25,000

$30,000

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23

Year

An

nu

al C

ost

Discount rate: 6%Life cycle period: 20 yearsNet Present worth: $39303Equivalent annual cash flow: $3427

Construction activity

Maintenance activities $150 per year

$150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150 $150

$25,000 Resheet$25,000 New surface

$0

$5,000

$10,000

$15,000

$20,000

$25,000

$30,000

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23

Year

An

nu

al C

ost

Discount rate: 6%Life cycle period: 20 yearsNet Present worth: $39303Equivalent annual cash flow: $3427

Construction activity

Maintenance activities $150 per year

Figure 9.1: Example life cycle analysis

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This example indicates that the annual cost of maintaining this pavement is $3,427 per kilometre. This cost should be compared to other strategies and the most appropriate strategy adopted. Other examples may include methods of increasing the life of the wearing course by, for example:

extending sheeting life to greater than 10 years

increasing the time between routine patrol grading.

9.2.3 Grading Intervention Frequency and Sheeting Life

Using the life cycle analysis methodology, the relationship between grading intervention and sheeting life on the operating costs of a pavement can be estimated as shown in Figure 9.2. It can be seen that increasing grading intervention frequencies beyond 12 months had little impact on life cycle costs. On the other hand, the benefit of increasing sheeting life was very significant. Therefore any process, e.g. blending materials or stabilisation that increases sheeting life, can have a significant cost benefit even though the initial prime costs are greater.

$1,500

$2,000

$2,500

$3,000

$3,500

$4,000

0 3 6 9 12 15 18 21 24 27 30 33 36

Months between patrol grading intervention

An

nu

al C

apit

alis

ed

Co

st P

er

Kil

om

etr

e

10 Years

20 Years

15 Years

12 Years

`

Pe

rio

d b

etw

een

re-

she

etin

g

Figure 9.2: Life cycle analysis of sheeting life and grading intervention

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REFERENCES

American Society for Testing and Materials 2006, Standard test method for measuring pavement macrotexture depth using a volumetric technique, ASTM E 965-96, ASTM International, West Conshohocken, PA, USA.

Andrews, RC 2000, Surface longevity treatments for unsealed roads, MTRD report 97/PA/056, Transport South Australia, Walkeley Heights, SA.

Andrews, RC 2001, ‘Opportunities for improved unsealed road asset management with chemical stabilisation’, ARRB Transport Research conference, 20th, 2001, Melbourne, Victoria, ARRB Transport Research, Vermont South, Vic., 21pp.

ARRB Transport Research 1998, Guide to the design of new pavements for light traffic: a supplement to Austroads pavement design, APRG report no. 21, ARRB Transport Research, Vermont South, Vic.

Australian Government 2004, NOHSC declares amendments to the exposure standards for crystalline silica: media release December 31, 2004, Australian Government, National Occupational Health and Safety Commission, Canberra, viewed 9 January 2009, <http://www.safework.sa.gov.au/uploaded_files/MR_Crystalline%20silica%20exposure%20standard%20amended.pdf>

Austroads 2003, Control of Moisture in Pavements During Construction, APRG technical note 13, Austroads, Sydney, NSW.

Austroads 2006a, Asset Management of Unsealed Roads: Literature Review, LGA survey and workshop (2000-2002), by L Dowling, AP-T46/06, Austroads, Sydney, NSW

Austroads 2006b, Guide to Pavement Technology: Part 4D – Stabilised Materials, by R Andrews & G Vorobieff, AGPT04D/06, Austroads, Sydney, NSW

Austroads 2007, Guide to Pavement Technology: Part 4 – Pavement Materials, by G Youdale & K Sharp, AGPT04/07, Austroads, Sydney, NSW.

Austroads 2008a, Guide to Pavement Technology: Part 4A – Granular Bases and Subbase Materials, by B Vuong, G Jameson, K Sharp & B Fielding, AGPT04A/08, Austroads, Sydney, NSW.

Austroads 2008b, Guide to Pavement Technology: Part 2 – Pavement Structural Design, by G Jameson, AGPT02/08, Austroads, Sydney, NSW.

Foley, G, Cropley, S & Giummarra, G 1996, Road dust control techniques: evaluation of chemical dust suppressants' performance, Special report no. 54, ARRB Transport Research, Vermont South, Vic.

Giummarra G (ed.) (in press), Unsealed roads manual: guidelines to good practice, 3rd edn, ARRB Group, Vermont South, Vic.

Giummarra, G 1998, ‘Better management of unsealed roads: estimating gravel loss: an innovative approach’, Road and Transport Research, June, vol.7, no.2, pp.84-85

Jones, TE 1984, The Kenya maintenance study on unpaved roads: research on deterioration, TRRL laboratory report 1111, Transport and Road Research Laboratory (TRRL), Crowthorne, UK.

Jones, D & Paige-Green, P 1996, ‘The development of performance related material specifications and the role of dust palliatives in the upgrading of unpaved roads’, Roads 96: Combined ARRB Transport Research conference, 18th, and Transit NZ land transport symposium, 1996, Christchurch, New Zealand, ARRB Transport Research, Vermont South, Vic., vol.3, pp.199-212

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Jones, D & Paige Green P 2000, TMH12: Pavement management systems: standard visual assessment manual for unsealed roads: version 1, Contract report CR-2000/66, CSIR Transportek, Pretoria, South Africa.

Jones, D, Sadzik, E & Wolmarans, I 2001, ‘The incorporation of dust palliatives as a maintenance option in unsealed road management systems’, ARRB Transport Research conference, 20th, Melbourne, Victoria, ARRB Transport Research, Vermont South, Vic., 16pp.

National Association of Australian State Road Authorities 1980, Pavement materials: part 2: natural gravel, sand clay and soft and fissile rock, NAASRA: Sydney, NSW. (Note : superseded in 2008 by Austroads Guide to pavement technology: part 4A: granular bases and subbase materials).

Organisation for Economic Cooperation and Development 1987, Maintenance of unpaved roads in developing countries: final report, OECD, Paris, France.

Paige-Green, P 1990, The economic optimisation of unpaved roads by improved material selection and construction techniques: final report, research report DPVT 106, CSIR Division of Roads and Transport Technology, Pretoria, South Africa.

Paterson, WDO 1987, Road deterioration and maintenance effects: models for planning and management, John Hopkins University Press for World Bank, Baltimore, MD, USA

Rushing, JF 2006, ‘Influence of application method on dust palliative performance’, ARRB conference, 22nd, 2006, Canberra, ACT, ARRB Group, Vermont South, Vic., 12pp.

Sanders, TG & Addo, JQ 2000, ‘Experimental road dust measurement device’, Journal of Transportation Engineering, vol.126, no.6, March, pp.530-5

Sossic, P 1987, ‘The Clegg hammer’, South Australia Highways Department, Road Construction Course 1987.

South Africa Department of Transport 2009, ‘Unsealed roads: design, construction and maintenance’, Report draft TRH 20, South African Department of Transport, Committee of State Road Authorities, Pretoria, South Africa

Standards Australia 2001, Method of testing soils for engineering purposes: soil strength and consolidation tests: determination of permeability of a soil: falling head method for a remoulded specimen, AS1289 6.7.2, SA, North Sydney, NSW

United States Department of Agriculture 1999, Transportation systems, November 1999, San Dimas Technology and Development Center, San Dimas, CA. USA

United States Department of the Army 1995, Unsurfaced road maintenance management, Technical manual TM 5-626, Department of the Army, Washington DC. USA

Wooltorton, FLD 1947, ‘Relation between the plastic index and the percentage of fines in granular soil stabilization’, Proceedings Highway Research Board, vol. 27, pp. 479-490.

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FURTHER READING

Barwick, PJ 1992, Energy efficient maintenance of roadside vegetation, Greening Australia, Hobart, Tas.

Cock, D 1993, ‘Managing unsealed roads in South Australia’, Legal Liability of Road Authorities, Seminar, 1993, Adelaide, South Australia, Australian Institute of Traffic Planning and Management, Thornleigh, NSW, 13pp.

Department for Industry, Tourism and Resources 2006, Mine rehabilitation: leading practice sustainable development program for the mining industry, Australian Government. Department for Industry, Tourism and Resources, Canberra, ACT.

Ferry, AG 1986, Unsealed roads: a manual of repair and maintenance for pavements, Technical recommendation TR-8, New Zealand National Roads Board, Road Research Unit, Wellington, New Zealand.

Ferry, AG & Major, NG 1997, ‘Strategies for grader maintenance of gravel roads’, National Local Government engineering conference, 9th, 1997, Melbourne, Victoria, Institute of Municipal Engineering, Sydney, NSW, pp.75-80

Fossberg, PE, Harral, C & Fiaz, A 1988, ‘Technical options and economic consequences for road construction maintenance’, IRF Middle East regional meeting, 3rd, Riyadh, Saudi Arabia, International Road Federation, Washington DC, pp. 3.57-3.69.

Moll, J 1993, ‘Paving of corrugated metal pipe inverts for repair and fish passage’, Engineering Tech Tips, July, 1993.

PIARC, TRL & Intech Associates 2002, Rural road surfacing: gravel/laterite (surface option no. 3), viewed 12 January 2009, <http://www.transport-links.org/transport_links/filearea/documentstore/Draft%20Gravel%20Guidelines.pdf>

Poyhonen, A 1995, ‘Methods for repairing frost damaged gravel roads’, International conference on low-volume roads, 6th, 1995, Minneapolis, Minnesota, Transportation Research Board, Washington DC, pp.149-154

Provencher, Y 1995, ‘Optimising road maintenance intervals’, International conference on low-volume roads, 6th, 1995, Minneapolis, Minnesota, Transportation Research Board, Washington DC, pp.199-207.

Standards Australia (various years), Manual of uniform traffic control devices, AS1742, SA, North Sydney, NSW