BEST PRACTICE GUIDELINES FOR SPECIFICATION OF MODERN NEGATIVE TEXTURE SURFACES (NTS) ON LOCAL AUTHORITY HIGHWAYS

BEST PRACTICE GUIDELINES FOR

SPECIFICATION OF MODERN NEGATIVE

TEXTURE SURFACES (NTS) ON LOCAL

AUTHORITY HIGHWAYS

Contents Page

No

1

EXECUTIVE SUMMARY

1

2

INTRODUCTION 3

2.1.

Overview and Objectives

3

2.2.

Code of Practice for Highway Maintenance Management

4

2.3.

Scope of Application and Use

6

2.4.

Terms and Definitions

6

2.5.

References 7

2.6.

Summary 7

3

PROCESS AND MATERIALS DEVELOPMENT

8

3.1.

Development History

8

3.2.

Generic Systems

11

3.3.

Proprietary Systems

13

3.4.

References 14

3.5.

Summary 15

4

SITE CONSIDERATIONS AND INSTALLATION 16

4.1.

General 16

4.2.

Serviceability 17

4.3.

Substrate – Existing Pavement

17

4.4.

Bond Coat

19

4.5.

Early Life Surface Characteristics

22

4.6.

Skid Resistance Characteristics

23

4.7.

Horses on the Highway

24

4.8.

Installation 24

4.9.

Installers and Inspection

26

4.10.

References 26

4.11.

Summary 26

5

THE RIGHT MATERIAL FOR THE RIGHT SITE 28

5.1.

Site Evaluation

28

5.2.

Chart A

30

5.3.

Chart B

30

5.4.

Chart C

30

5.5.

Chart D

30

5.6.

Chart E

36

6

EXPIRED LIFE ENGINEERING

39

6.1.

Introduction 39

6.2.

Failure Groups

39

6.3.

Types of Deterioration

40

6.4.

Deterioration Model

43

6.5.

References 52

6.6.

Summary 52

7

LOCAL AREA REINSTATEMENT

53

7.2.

Reinstatement Size and Position

55

7.3.

Installation and Compaction

55

7.4.

Street Furniture and Ironwork

57

7.5.

Summary 58

8

ASSET MANAGEMENT

59

8.1.

Asset Management Plan

59

8.2.

Whole Life Costing

59

8.3.

Winter Maintenance

61

8.4.

Distress Mechanism and Forecast

61

8.5.

References 62

8.6.

Summary 62

Figures

Figure 1 - Structure and relationship of Best Practice Guidelines

5

Figure 2 - Schematic diagram of positive and negative textures.

6

Figure 3 - Chart A

31

Figure 4 - Chart B

32

Figure 5 - Chart C (1 of 2)

33

Figure 6 - Chart C (2 of 2)

34

Figure 7 - Chart D

35

Figure 8 - Chart E (1 of 2)

37

Figure 9 – Chart E (2 of 2)

38

Figure 10 – Fattting-up

41

Figure 11 - Fretting

45

Figure 12 - Mini paver machine

53

Figure 13 -Whole Life Cost

60

Tables

Table 1 - British Standard surfacing mixtures for thin layers

9

Table 2 - Classification of Bond Coats by Vialit Test Value

20

Table 3 - Classification of bond coats by torque bond strength

21

Table 4 - Selection of Bond Coat

21

Table 5 - Site evaluation checklist

29

Table 6 – Elements of a Deterioration Model

44

Appendices

Appendix A - Functional Carriageway Hierarchy

64

Appendix B - Glossary of Terms and Definitions

65

Appendix C - Questionnaire

67

Appendix D – Summary of Responses

68

Appendix E - Regional Workshops

71

Appendix F - BBA Scheme Guidance

72

Appendix G - Investigation Protocols

73

Appendix H – Specifying Proprietary Materials

77

Appendix I – Installers Observations

81

1 EXECUTIVE

SUMMARY

These Best Practice Guidelines for Negative Texture Surfaces (NTS) provide a methodology for site evaluation and material selection, to ensure that the right material is installed in the right site, together with a structured approach to the factors which may have a bearing on distress mechanisms.

•

Enquiry responses have indicated generally that NTS is performing equally well or better than traditional materials in most circumstances on local authority highways.

•

Substrate condition evaluation is essential in the selection of NTS on evolved local authority highways.

•

The surface layer on thin local highways can constitute a significant proportion of the sound bituminous material in the pavement structure.

•

The wide variety of proprietary system surfaces which are available broadens the scope of sites that are potentially suitable for their application. However, there are many situations where generic types of surface material may provide serviceability at best value.

•

A rational approach to the engineering selection of NTS is provided as a series of flow diagrams.

•

A checklist together with a series of decision charts enables a consistent approach for site evaluation by consideration of five distress modes for the substrate.

•

An investigation of the existing carriageway is particularly important for thin flexible local pavements to ensure optimum maintenance designs. Investigation protocols have been developed to support this.

•

A surface material decision chart considers key engineering performance requirements to ensure strain compatibility between surface layer material and support substrate.

•

A process of bond coat selection is developed to ensure good in-service adhesion between the surface and the substrate.

•

All sites for surfacing should be inspected and evaluated by experienced and knowledgeable personnel with joint client/contractor inspection as appropriate.

•

An assessment should be undertaken of the period of time required for removal of binder film in early life through vehicle wheelovers.

•

Attention to detail in the location and formation of joints, especially in highly stressed areas will avoid premature distress in an otherwise serviceable surface.

•

Fretting and cracking were found to be the most significant mechanisms of deterioration in NTS.

•

Five factors of influence for causes of distress of NTS have been determined and related to a mechanistic deterioration model. The influencing factors do not always behave in isolation and are frequently inter-dependent.

•

For local area repair the care and preparation of the area to be reinstated is at least as important as the installation of the surface material itself.

•

Failure of NTS, when it occurs, can be a swift process. A procedure to predict the onset of distress by forecasting has not been

identified. This is a significant area for future study, since the absence of an appropriate deterioration model could result in lack of certainty in asset management planning.

2 INTRODUCTION

2.1.

Overview and Objectives

2.1.1. Negative Texture Surfaces (NTS) comprise a family of modern asphalt materials which have been developed to provide safe, durable and quieter highway surfaces. The common feature of NTS is that surface texture, an essential component of skid resistance, is provided in a downward (negative) direction beneath the vehicle tyres. The NTS family comprises a suite of proprietary surfaces, known collectively as thin surfacings and generic stone mastic asphalt. Thin surfacings were developed to provide safety through the adequate provision and retention of negative texture over time. Generic stone mastic asphalts used in the UK have been modified from the original European materials to provide a sufficient installed surface texture.

2.1.2. The Roads Liaison Group (RLG) was established in 2001 in order to advise local authorities and Central Government on highway maintenance issues. Members of RLG include the Department for Transport (DfT), the Local Government Association (LGA), and representatives of national and local highway authorities in England, Scotland, Wales and Northern Ireland. The RLG is supported by four boards - Roads, Bridges, Lighting and Traffic Management. This project was commissioned by the DfT on behalf of the UK Roads Board and these Best Practice Guidelines have been developed for application on the local authority highway network.

2.1.3. A major element of local road maintenance relates to the surface course of the highway. Hot rolled asphalt (HRA) surface course was the standard road surface material throughout the country for very many years but this traditional, virtually impermeable, positive surface texture material has swiftly given way to NTS.

2.1.4. The terms “thin surfacing” (TS) and “stone mastic asphalt” (SMA) have been in common use for about a decade and consequently they have been retained in this document but all such materials belong to the highway surface performance family of NTS materials.

2.1.5. The impact of NTS has been so great that some authorities have virtually ceased to use traditional rolled asphalt surfaces. The rapid introduction, however, has meant that there has been little time for longer term performance lessons to be learnt on the network.

2.1.6. Local authority enquiry responses undertaken during development of these Guidelines have indicated, overall, that NTS is performing as well or better than, traditional materials in most circumstances where the right material has been installed in the right site. Development of innovative surface materials will continue in the future with advancing technology and therefore these Guidelines are not timeless. These Guidelines should be reviewed within an elapsed period of five years to accommodate any new developments, incorporate performance feedback, consider the implications of further research and address the introduction and embedment of European Standards for asphalt surface materials.

2.1.7. The core objective of these Best Practice Guidelines is to define distress conditions of NTS to aid both engineering understanding and asset management planning for the network. This will assist in a managed change from reactive to programmed maintenance as recommended in the Code of Practice for Highway Maintenance Management. These Guidelines have been developed to enable a rational decision making and selection process for NTS materials.

2.2.

Code of Practice for Highway

Maintenance Management

2.2.1. The Code of Practice for Highway Maintenance Management, “Well Maintained Highways”, describes good practice and sets out a series of recommendations for highway authorities to implement.

www.roadscodes.org

2.2.2. Figure 1 illustrates the relationship of these Best Practice Guidelines for NTS with the Code of Practice, asset management and local transport planning.

2.2.3. These Guidelines should be read in the context of these documents, as they provide more detailed guidance for the application of NTS in the delivery of the core objectives of the Code of Practice:

•

Safety;

•

Serviceability;

•

Sustainability;

Government Transport Policy

Local Transport Planning Guidance Codes of Practice Highway Maintenance Management Management Of Highway Structures Highway Lighting Management Best Practice Guidelines Negative Texture Surfaces (NTS)

CSS Framework for Highway Asset Mnaagment

Figure 1 - Structure and relationship of Best Practice Guidelines

2.2.4. The Code defines carriageway hierarchy functionality which is reproduced in Appendix A. It is recommended that this hierarchy should be developed by an authority to take into account current and expected traffic characteristics. It is this relationship between traffic and hierarchy that is developed later in these Guidelines as the basis for selection of surfacing. This approach is consistent with the Code and local transport planning. The hierarchy and subsequent design approach adopted for surfacing should also be consistent with adjoining authorities, to meet road users’ reasonable expectations. 2.2.5. In the selection of surfacing, authorities should consider both the

future maintenance implications of the surfacing together with any environmental implications. The Code provides designers with check lists to assist with the development of designs for each of these aspects. These checklists should be used by surfacing specifiers in the context of these Guidelines. Local Transport Plan guidance identifies that additional maintenance costs arising from all new and improved infrastructures should be explicitly identified and taken into account in evaluating the whole life cost of the scheme. This will include the surfacing aspects of the maintenance or improvement works.

2.3.

Scope of Application and Use

2.3.1. Distress which has occurred in NTS has generally been attributed to inappropriate site conditions, selection of material or installation practices. These factors are much more significant on the local network than on the strategic network. This is due to the evolved nature of the local network, its more variable construction, geometry, junctions, layout and the frequency and scale of highway maintenance works.

2.3.2. The development of these Guidelines was undertaken through dialogue with a number of stakeholders, including clients, specifiers, installers and highway maintenance engineers, together with examination of the surfacing failure mechanisms. This was conducted with the objective of producing robust guidance of value to the profession.

2.3.3. The early life surface frictional characteristics of negatively textured surfaces are not within the scope of these Guidelines and are covered in detail elsewhere. However, the overall mechanisms are reviewed insofar as they inform a distress condition.

2.3.4. The focus of the Guidelines is “the right material for the right site” to ensure value for money and maximum longevity in service. The guidelines are articulated through engineering performance and materials science factors. Decision charts provide a process for site evaluation and surface materials selection. No attempt is made to define which material should be used in particular circumstances but the Guidelines provide a broad mechanism for structured evaluation and choice of surfacing type in a highway maintenance context.

2.4.

Terms and Definitions

2.4.1. The provision of surface texture on a pavement is a key difference between traditional surfacing, such as HRA, and the family of NTS materials. Positive texture as provided by HRA with chippings and negative texture as provided by NTS is illustrated in Figure 2.

Figure 2 - Schematic diagram of positive and negative textures.

2.4.2. There is no universally agreed categorisation for TS, even the limits of the term thin surfacing are ill-defined as the materials have developed and evolved. Terms and definitions are described in Appendix B and are based upon those published previously (Nicholls, Carswell and Langdale, 2002) but adapted and extended to address the wider scope of surfacing solutions that are the subject of these Guidelines.

2.5. References

1. Well Maintained Highways. Code of Practice for Highway Maintenance Management (2005), The Stationery Office, London. ISBN 0-11-552643-9

2. Walsh I.D. (2000), “Out of the skid pan”. Surveyor, 9th November 2000, pp12-15

3. Nicholls J.C, Carswell I. and Langdale P.C. (2002), “Durability of thin asphalt surfacing systems. Part 1 Initial findings” TRL Report 557, TRL Limited.

2.6. Summary

•

These Best Practice Guidelines provide underpinning support for “Well Maintained Highways”.

•

Surfacing selection should be based upon highway functionality.

•

Future maintenance implications should be considered in surfacing selection.

•

Surfacing distress is related to inappropriate choice of site, installation and materials selection.

•

Local highway networks have evolved with variable construction, geometry, junctions and layout.

•

The scope of the Guidelines includes both generic and proprietary surfacing.

•

The Guidelines were developed through extensive consultation with stakeholders.

3 PROCESS AND MATERIALS

DEVELOPMENT

3.1. Development

History

3.1.1. Before the availability of NTS the traditional surface course materials for pavements in the UK were HRA with high polish resistant pre-coated chippings, dense or close graded bitumen macadam (DBM) and surface dressing (SD). High stone content asphalt (HSCA), which has no surface applied pre-coated chippings, was also a frequently used surface material.

3.1.2. Selection of the surfacing material was dependent on:

•

Traffic levels;

•

Availability and cost of suitable crushed rock aggregate;

•

Condition of substrate;

•

Intended laying season.

3.1.3. The service life of HRA surfaces was generally between ten and twenty years and in some specific cases significantly longer. After this period it could be overlain by a new HRA surface course if levels permitted and this added significantly to the structural strength and flexibility of the pavement as a whole.

3.1.4. DBM (or close graded macadam) surfacing was a common choice on minor highways. It was generally expected to have a typical service life of between eight and fifteen years although during this period it may require surface dressing (SD) treatment. As with HRA it could be overlaid at the end of its service life and would continue to contribute to the structural strength of the pavement.

3.1.5. Many contractors developed variations on the British Standard BS 4987 close graded mixtures with more exacting control limits on the grading and special binder types. Such materials were used successfully in urban areas where thin overlays were required to address difficulties with access levels. Although many proprietary systems and local specifications provided for relatively durable surfacing down to 25mm nominal thickness, as did BS 4987, materials which could confidently be laid on more heavily trafficked or highly stressed sites were not available. Table 1 illustrates the BS surfacing mixtures which can be installed at thicknesses of 35mm or less.

Table 1 - British Standard surfacing mixtures for thin layers British Standard Description Aggregate size (mm) Thickness (mm) Reference BS 594-1 15% Stone content 0/10 30 Table 6, Col 6/2 BS 594-1 30% Stone content 0/10 35 Table 6, Col 6/3 BS 4987-1 Fine graded surface course 0/4 15 - 25 Clause 7.7 BS 4987-1 Medium graded surface course 0/6 20 - 25 Clause 7.6 BS 4987-1 Dense surface course 0/6 20 - 30 Clause 7.5 BS 4987-1 Porous asphalt surface course 2/10 30 - 35 Clause 8.2 BS 4987-1 Close graded surface course 0/10 30 - 40 Clause 7.4

Note: The above table is a means of illustration only and should not be taken as implying suitability of a particular surface.

3.1.6. A revision of Chapter 8 of the Traffic Signs Manual, in the early 1990s introduced a requirement for a safety barrier zone between operatives, plant and active traffic. For most rural and many urban highways this safety zone requirement meant that the machine application of chippings to the surface of HRA could not be used without a complete road closure.

3.1.7. At about the same time as the introduction of the increased construction site safety measures, some asphalt manufacturers were developing SMA and derivative materials. These products were based on continental practice, particularly German splittmastixasphalt. Other manufacturers chose to take out licences for the production of similar surface products which had already been developed overseas. The adoption and use of these materials reduced the contractual risk associated with chipping on HRA and also needed less resources for installation. Thus, the use of HRA, which was the favoured surface course material for many situations, became problematic and fell into reduced use.

3.1.8. Early NTS products included the Jean Lefebvre ULM thin asphaltic concrete, originally licensed to A. McAlpine Ltd, and Safepave, a paver-laid surface dressing licensed to Associated Asphalt Ltd. As these products were already fully developed they were capable of immediate larger scale application and were quickly adopted on a trial basis by many authorities.

3.1.9. The development, and client acceptance, of mixtures based on the German splittmastixasphalt, known in English speaking countries as SMA, lagged slightly behind the acceptance of the licensed systems.

In Northern Continental Europe the requirement was for durable dense surfacing mixtures for heavy traffic conditions. The delivery of optimum skid resistance, whilst desirable, did not assume the same priority as in the UK. The German practice was to use a relatively stiff bitumen binder with high bitumen content and high stone content. The lack of fine aggregate and filler in the mixture could lead to bleeding of bitumen during transport and laying. To guard against this the splittmastixasphalt mixture normally included cellulose fibres to partially immobilise the bitumen before laying.

3.1.10. The UK skid resistance requirements necessitated the provision of significant macro-texture depth. The specifications were relatively easily met by HRA with pre-coated chippings but with splittmastixasphalt formulations the stone matrix was virtually fully filled with bitumen. In developing UK equivalents, suppliers needed to be able to reduce the relative volume of binder-filler matrix. This was to allow adequate texture to remain on the surface after compaction. To ensure low permeability and therefore good durability, the bulk of the layer was fully filled with bitumen mastic. This compromise was satisfactorily achieved at bitumen contents in the order of 6%-7% by mass. The mixtures were particularly stable with aggregate interlock providing good resistance to wheel track rutting. Previous experience of bitumen rich SMA in Northern Europe had shown rutting under heavy traffic conditions.

3.1.11. Early versions of SMA in the UK suffered with development problems when the ratio of layer thickness to nominal stone size was less than two. Most of the currently available SMA and Thin Asphalt Concrete (TAC) variants now have a minimum layer depth close to, or in excess of, twice their nominal stone sizes.

3.1.12. Based upon trials and the use of SMA as a high stability surface course material (Nunn, 1994), many authorities developed generic specifications for the material and its installation.

3.1.13. Owing to the many proprietary surface systems which had entered the market, a product type approval evaluation system was developed by the Highways Agency. This process required the system proprietor to lay a trial site, usually on a trunk road. The manufacture and installation was monitored together with laboratory testing and upon completion of the trial a panel of experts inspected the site. The inspection process was repeated at regular intervals for at least two years.

3.1.14. Requirements for bituminous surface material and techniques to be used on the strategic network are encapsulated in the Design Manual for Roads and Bridges (DMRB) HD 37/99. Site trials confirmed the German experience that generic SMA mixtures are sensitive to small variations in aggregate grading and binder content. This can result in a reduction in surface texture as evidenced by a localised patchy appearance and fatting of the surface. Potential inconsistency in terms of texture retention, which is essential for high speed skid resistance means that SMA produced to a generic specification must not be used on the Highways Agency network. However, the constraints of traffic management and congestion on the local network are not so great and generic SMA has continued to be used. Additionally, there are differing

speed limits which are not so texture dependant enabling the installation of mixtures, which may be less exacting in this performance parameter than is the case for trunk roads.

3.1.15. The type approval scheme, although used by authorities as a specification requirement for NTS was not entirely appropriate for non-trunk road application. In 1995 the CSS and Highway Agency established the Highway Authorities Product Approval Scheme (HAPAS) to enable independent certification of the performance of proprietary surfacing products and systems. The British Board of Agrément (BBA) was appointed to administer the scheme. A specialist advisory group (SG3) was established in 1996 to broaden the scope of the product approval scheme. SG3 developed “Guidelines for the Assessment and Certification of Thin Surfacing Systems”. Various proprietary thin surfacing systems were assessed with the first certificate issued in 2000. By November 2005 twenty seven proprietary systems had been certified. Throughout these Guidelines the term product is taken as referring to the manufactured material and the term system to the product and its installation protocol.

3.1.16. The introduction of BBA certification did not make the use of generic specifications redundant. Over half of all authorities specify SMA surfacing by generic means for their network applications. These generic SMA specifications have generally been evolved in collaboration with local asphalt manufacturers to suit the local availability of mineral resources and local network needs. Some authorities use both generic specification and BBA certification selectively as the site requirements dictate.

3.2. Generic

Systems

3.2.1. British Standards, BS 594 for HRA and BS 4987 for Coated Macadam (asphalt concrete), provide a limited spectrum of surfaces suitable for layer thicknesses of less than 40mm.

3.2.2. Tables 3 and 4 of BS 594-1 provide only a 0/2mm nominal size aggregate designed asphalt mixture for laying at 25mm thickness. The sand carpet mixture is unsuitable for carriageway surfacing application due to low surface macro-texture and potential mix instability. Table 6 of BS594-1 provides recipe specifications for 15% stone content 0/10mm nominal size mixtures for laying at a thickness of 30mm and a 30 % stone content, 0/10 nominal size mixture for 35mm thickness. The former material is generally only regarded as suitable for footway and very light vehicle use. The 30% (0/10) mixture can be used for light traffic application but the non-availability of a design mix equivalent inhibits its wider acceptance, particularly in areas where the native sand tends to produce unsuitable mixtures. However, with critical formulation and the use of modern polymer bond coats, the 30% (0/10) mixture may well be capable of meeting many of the requirements of a thin surfacing system, if designed in accordance with the principles of Specification for Highway Works (SHW) Clause 943. Since Clause 943 does not include for modification to the 30% (0/10) mixture the resultant material would need to be specified as a special material or manufactured as a proprietary product.

3.2.3. BS 4987 has been the traditional source for the specification of thin surfacing layers. Many of these British Standard formulations perform well and when specified and installed in appropriate situations in the network provide good value for money. BS 4987-2, Table 6 specifies nominal and minimum layer thicknesses for coated macadam indicating seven mixtures capable of being laid at depths of 35mm or less. The 0/10 close graded surface course is suitable for general highway use but the 0/6 dense surface course material cannot be relied upon to provide adequate surface texture depth for higher speed applications. The open graded mixtures can provide adequate surface texture but can fret in high lateral stress areas. The 0/10 close graded mixture is unlikely to produce a texture depth suitable for areas with a speed limit above 30mph. As with the 0/10 HRA mixture, the use of a premium (high performance) bond coat could make the use of conventional material more reliable under relatively heavy trafficking. 3.2.4. The generic SMA specifications used by authorities include the

following essential requirements and are based upon the style of specification in PR 65 (Nunn, 1994). However many authorities adapted their specifications locally with bespoke modification of composition and other aspects to reflect serviceability, resource constraints and installation requirements, which have been developed over time in collaboration with local asphalt manufacturers. The core features comprise:

•

A permitted range for the target grading envelope;

•

A range of potential tolerances to be applied to the suppliers chosen grading curve;

•

Maximum and minimum binder content;

•

An air void requirement in the designed mix.

3.2.5. Forthcoming European Specifications for asphalt will impact on current British Standards specifications for surface materials. The relevant parts of the emergent technical standards are:

•

EN 13108-1 Bituminous mixtures – Part 1 Asphalt Concrete;

•

EN 13108-2 Bituminous mixtures – Part 2 Very Thin Layer Asphalt Concrete;

•

EN 13108-5 Bituminous mixtures – Part 5 Stone Mastic Asphalt;

•

EN 13108-7 Bituminous mixtures – Part 7 Porous Asphalt.

3.2.6. All of the above four parts of EN 13108 are progressing through the European Standards body, CEN, and are likely to be implemented in the UK by 2008.

3.2.7. EN 13108-2 makes reference to an intended installed layer thickness of between 20mm and 30mm. Asphalt concrete surfacing greater than 30mm thick will be specified to EN 13108-1. Layers less than 20mm in thickness will also be covered by EN 13108. Asphalt concrete products 10mm to 20mm in thickness may be capable of submission for product approval certification.

3.2.8. Porous Asphalt is specified in the Specification for Highway Works, (Nov 2004 amendment), and a similar material, but less definitively described, is included in BS 4987-1. Both materials have 6/20 mm

nominal size aggregate and are placed at 45mm to 50mm in thickness. BS 4987 also includes a 2/10mm nominal size mixture, which may be laid at thicknesses of 30 to 35mm. Porous asphalt has advantages over close graded mixtures in respect of noise and spray reduction. However, it is little used on local roads because of limited structural contribution, winter maintenance management and relatively poor durability.

3.3. Proprietary

Systems

3.3.1. Thin surfacing systems may be certified by BBA through the HAPAS mechanism. All thin surfacing systems for use on trunk roads must be BBA certified. Some authorities also make certification mandatory on their network whilst others require BBA certification only for selected parts of their network.

3.3.2. To achieve certification a system proprietor must satisfy the process requirements of the BBA “Assessment and Certification of Thin Surfacing Systems for Highways”. The certification is described in full in Section 3 of the BBA protocol and is summarised as follows:

3.3.3. Stage 1: Assessment of applicant submitted data

•

Company details;

•

System details and history;

•

A quality plan covering;

•

binder type(s);

•

aggregate source(s), characteristics etc;

•

ancillary products detail;

•

final products, thickness, composition etc;

•

Details of total quality structure and system;

•

Installation method(s).

3.3.4. Stage 2: Assessment of factory production control:

•

Subsequent site and plant inspections by BBA. 3.3.5. Stage 3 Laboratory testing (Mandatory):

•

PSV and AAV test on proposed aggregates;

•

Wheel tracking;

•

Sensitivity to water;

•

Torque bond test for assessing the adhesion at the layer to the substrate;

•

Visual assessment;

•

Texture depth.

3.3.6. Stage 3 Laboratory testing (Optional):

Optional tests carried out by the BBA, based upon in-house protocols, to evaluate properties within a menu which an applicant system proprietor may elect to have included on their certificate. The properties that may be covered include:

•

Stiffness;

•

Retained stiffness after fuel immersion;

•

Ageing;

•

Resistance to binder stripping;

•

Noise reduction relative to HRA;

•

Regulating ability;

•

Hydraulic conductivity;

•

In service skid resistance. 3.3.7. Stage 4 – Installation Trial:

•

Construction of a section of surfacing witnessed by the BBA;

•

The installation is subject to laboratory testing as required by BBA. 3.3.8. Stage 5 – Performance Trial:

•

Each trial section is monitored and tested for a period of two years and any loss of texture recorded;

•

Expert panel inspections are carried out at the end of the two year evaluation period.

3.3.9. Stage 6 – Certification

•

Certificates verify the system compliance with BBA requirements, define the systems assessed, the conditions of application, likely performance and the results of laboratory and site tests;

•

Once certified a system may not be changed without the approval of BBA;

•

The acceptability of any proposed changes to a system will be evaluated by further testing as BBA require;

•

Audits of each system are conducted at least annually;

•

Full review of each system is undertaken by BBA every five years. 3.3.10. BBA certificates which have been issued for proprietary thin surfacing

systems are available at www.bbacerts.co.uk .

3.4. References

1. British Standard Institution, (2005). BS 594-1 “Hot rolled asphalt for roads and other paved areas. Specification for constituent materials and asphalt mixtures” BSI, London.

2. British Standard Institution, (2003). BS 594-2 “Hot rolled asphalt for roads and other paved areas. Specification for transport, laying and compaction of rolled asphalt” BSI, London.

3. British Standard Institution, (2005) BS 4987-1 “Coated macadam (asphalt concrete) for roads and other paved areas. Specification for constituent materials and mixtures” BSI, London.

4. British Standard Institution, (2005) BS 4987-2 “Coated macadam (asphalt concrete) for roads and other paved areas. Specification for transport, laying and compaction” BSI, London.

5. Nunn M.E. (1994) “Evaluation of Stone Mastic Asphalt (SMA): A high stability wearing course material” TRL Project Report 65, TRL Limited. ISSN 0968-4093.

6. Highways Agency. Manual of Contract Documents for Highway Works, Volume 1: Specification for Highway Works, The Stationery Office, London.

7. Highways Agency. Design Manual for Roads and Bridges. Volume 7, Section 5 “Bituminous surfacing materials and techniques”. HD 37/99 Amd No1, The Stationery Office, London.

3.5. Summary

•

Introduction of improved safety standards and reduction of risk associated with installation of NTS, led to the decline of traditional HRA as the preferred surface material.

•

NTS materials, originally based upon continental European practice, have been modified to provide adequate surface texture for use in the UK.

•

Proprietary thin surfacing in the UK has evolved and is now certified by the BBA through the HAPAS protocol. A summary of the certification process is provided for ease of reference and understanding.

4

SITE CONSIDERATIONS AND

INSTALLATION

4.1. General

4.1.1. A thorough understanding of the engineering performance of the existing pavement substrate upon which the surface is to be placed is a key factor for maintaining serviceability.

4.1.2. Key elements comprise:

•

A suitably resilient substrate on which to place the surface material;

•

Selection of an appropriate surface material or system.

4.1.3. An enquiry questionnaire presented in Appendix C was issued to all highway authorities to establish local aspects for surfacing related to:

•

Site situation;

•

Materials;

•

Performance prediction;

•

Serviceability and performance.

4.1.4. The summary findings from the questionnaires are presented in Appendix D and illustrate:

•

Cracking and fretting to be the most common failure mechanisms;

•

The key role of the substrate;

•

The importance of bond with the substrate;

•

Approximately equal use of generic and proprietary specifications;

•

Surface serviceability, in general, was good or better than traditional materials, but performance in high stress situations was indicated not to be quite so good.

4.1.5. Analysis of the enquiry questionnaire response led to regional interactive participatory workshops in Birmingham, London and Huddersfield. The format for these workshops is summarised in Appendix E and provided the opportunity for practising maintenance engineers to address the issues of:

•

Site evaluation;

•

Materials selection.

4.1.6. The views of a cross section of installers with experience in NTS were sought in parallel with authority enquiries. These observations are summarised in Appendix I and contributed to the subsequent development of decision charts for substrate evaluation and material selection which followed the participatory workshops.

4.2. Serviceability

4.2.1. The local highway has generally evolved over time. For a typical length of carriageway various structural strengthening, surfacing or repair treatments have been undertaken in the past. These measures have resulted in a network which is variable both in terms of thickness and types of construction materials. Consequently, these pavements are significantly different from designed highways such as motorways which perform in a stable and long life manner. In comparison, the local highways are much thinner and more susceptible to structural changes resulting from increased traffic loading and subgrade moisture conditions.

4.2.2. Over time the local highway has come into equilibrium with its surroundings including underlying soil conditions, traffic loading and drainage. Many of the materials used in previous construction and repair are not now in common use and as a result of just in time maintenance practices may have become distressed through cracking and embrittlement. The relative proximity of the subgrade results in the thinner pavement being intrinsically more flexible in its structural behaviour under traffic loading. At the surface there are many traffic braking, accelerating and turning manoeuvres and consequently any surfacing material has to be capable of absorbing these forces in addition to working in harmony with the underlying pavement.

4.2.3. Compatibility of strain is important if the surfacing is to perform well in service. The inclusion of a stiff brittle layer in an otherwise relatively flexible structure is unlikely to yield longevity of performance. The selection of surfacing therefore, needs to consider the ability to provide strain compatibility, as well as the polishing resistance and texture characteristics, which are necessary for safety. The nature of the evolved pavement and the condition and type of pre-existing materials requires that careful consideration should also be given to the porosity of the new surface material. The introduction of water through a more porous surface can lead to serviceability distress, especially when the pavement is in an existing state of limiting equilibrium. This can be ameliorated with the use of bond coat and an impermeable binder course, providing there is an effective drainage system for the carriageway.

4.3.

Substrate – Existing Pavement

4.3.1. The condition of the existing pavement which will form the support platform for the surface is a key factor in the overall performance. 4.3.2. Five distress features form the basis of condition evaluation for the

existing road:

•

Oxidisation;

•

Fretting;

•

Cracking;

•

Texture;

•

Rutting.

4.3.3. Oxidisation of the surface results in a dull or burnt appearance due to the degradation of the exposed hydrocarbon binder. This can result in wrinkle cracks and the road surface has a tired appearance since the binder component has reached the end if its ductile life. The depth of distress is probably not great unless the oxidisation is well advanced or other deeper seated distress factors are also present.

4.3.4. Fretting of the aggregate and/or matrix from the pavement surface occurs when the micromechanical bond between binder and aggregate reaches a critical point. The mechanisms which cause this to occur are complex and frequently interactive but are likely to be triggered by environmental factors. Rapid failure can occur with water pressure and suction effects on the surface resulting from the passage of vehicle tyres. In a matrix dominated material, such as HRA, this process occurs slowly as these materials are generally impermeable and environmental intrusion is very limited, but in aggregate dominated materials, such as NTS, once the lateral support of one particle is lost, fretting can occur swiftly and progressively.

4.3.5. Cracking of an existing surface is frequently the most difficult to define. From a surface material selection perspective it is important to establish if the cracking is surface initiated and is propagating downward or has been initiated at depth and propagating upwards. If the root cause of the cracking incorrectly diagnosed then a replacement surface may simply crack again after a relatively short period of service life. Three principal types of cracking have been established:

•

Longitudinal;

•

Map;

•

Transverse.

4.3.6. Dependent upon severity and crack propagation direction, a single layer, two layers or multi layer solution may be required and in some cases the inclusion of a Stress Absorbing Membrane Interface (SAMI) may provide additional safeguard against crack propagation.

4.3.7. Surface texture is a key safety feature for high speed skid resistance. Any texture loss or gain will only occur within the existing surface layer and is a defect which can be corrected relatively easily with a single layer solution.

4.3.8. Rutting can owe its origin either in the surface course (non-structural rutting) or from a deeper seated origin, and it is important to identify the root cause. Non-structural rutting, which is caused by deformation within the surface, is generally accompanied by horizontal pushing of material at the margins of the longitudinal rut. Deeper seated rutting has a more general depressed area beneath the overall surface level. Both surface material rutting and deeper seated rutting can yield the same numerical measure of rut depth but cause must be understood in order to ensure an effective surfacing solution.

4.3.9. The addition of an overlay, wherever practicable, will add to the overall structural capacity of the pavement. There is little published information on the extended structural life for overlays which are less than 40mm in thickness. However, it is considered that overlays of

30mm thickness do offer some structural contribution to thin evolved pavements The structural contribution effect of an overlay 40mm or greater in thickness can be considerable (Kennedy and Lister, 1978). In situations where the pavement can be overlain with a new surface then this should be the first choice option.

4.3.10. Where access levels or other physical features prevent the addition of an overlay, then an inlay may be the only practical solution. This is frequently the case in urban areas where the existing defective depth of pavement may have to be removed and new surfacing material installed in its place. Inlay construction generates aged material from the existing pavement which may be recycled in-situ or elsewhere. However, the inlay itself is unlikely to provide much direct improvement in structural terms, other than degraded material being replaced with new material, resulting in the exclusion of surface water by a newer and less permeable surfacing.

4.3.11. In some urban kerbed areas it may be possible to channel plane close to the kerb edge to enable the new surfacing to be installed to the previous road level at the kerb. The remaining central portion of the road is not milled and in effect there is an inlay at the edge and overlay in the centre. The key area is the transition from inlay to overlay at the milled step in the existing pavement. When a new surfacing is installed in this fashion the thickness can be at its thinnest at this point and this may be directly in alignment with the nearside wheel track.

4.3.12. Where planing operations in the existing pavement are required to enable inlay surfacing, care should be taken to ensure that the planed depth is such that each old layer which is disturbed is removed in its entirety. The thickness of the existing layers and their condition will be known from investigation or local knowledge. Remnants of old layers which are not removed can have a detrimental effect on the in-service performance of the inlay.

4.4. Bond

Coat

4.4.1. All pavement layers need to be bonded to the layers above and/or below to assure the maximum structural efficiency of the whole pavement structure under vertical loading.

4.4.2. An effective bond between layers enables horizontal shear stress between layers to be transmitted. Greatest efficiency is obtained where the horizontal shear strain in a bond coat is small and approaches that in the adjacent asphalt layers. Horizontal shear stresses are small by comparison with the tensile stress in the overall pavement but nonetheless need to be fully transmitted.

4.4.3. Adhesive bond becomes critical in near surface layers. At points remote from an applied wheel load normal stresses can be tensile and thus no frictional transmission of horizontal shear is possible and total reliance must be placed on the bond coat. Additionally, at shallow depths the horizontal shear forces due to braking, turning, traction on gradients, and differential thermal movements are far more concentrated than at greater depths.

4.4.4. The efficient transmission of horizontal shear stress is critical to the function of the pavement as a whole. The bond coat is essential to ensure the survival of the surface course. Fretting, cracking and delamination have been recorded to be the most serious and frequent forms of deterioration of NTS and since fretting and delamination are frequently initiated by cracking it follows that a good bond coat is also beneficial in slowing failures due to cracking.

4.4.5. Virtually all thin surfacing systems are more permeable than the HRA material they have replaced. The ingress of water particularly in un-designed pavements is the major cause of deterioration. Thick bond coats can act as a water barrier and assist in extending the life of a pavement. However, the existence of a horizontal water barrier puts particular importance on the performance of the surface layer when saturated.

4.4.6. BS594 and BS4987 define tack coat as K1-40 or K1-60 bitumen emulsion conforming to BS434-1 and bond coat as proprietary material having performance characteristics certified by BBA. When certifying a complete thin surfacing system, rather than a bond coat, BBA also differentiate between tack coat and bond coat. The certified torque bond values on a BBA certificate only usually relate to a single tack/bond coat even when the certificate covers a number of bond/tack alternatives.

4.4.7. The Notes for Guidance on the “SHW Clause 920” Bond Coats, Tack Coats and other Bituminous Sprays suggests a classification into three categories, based upon the Vialit Pendulum Energy Loss Test as illustrated in Table 2.

Table 2 - Classification of Bond Coats by Vialit Test Value

Classification Vialit pendulum, peak cohesion value (J/cm2)

Conventional (UV) >0.5*

Intermediate (IV) >1.0

Premium (PV) >1.2

*Inferred from Table NG913

4.4.8. Alternatively, bond coats may be classified by the torque bond test. The torque bond strengths in Table 3 are derived for the BBA certificated values. Test variability combined with substrate variability make the application of this approach difficult for site specific application and therefore, the use of the values in specifications is not recommended until further research is completed. The ranges in Table 3 are based upon best available knowledge and may benefit from revision in the future but illustrate three categories of classification for bond coat. If site measured values of torque bond strength are less than forty percent of the values shown in Table 3 then further investigation should be carried out.

Table 3 - Classification of bond coats by torque bond strength

Classification Torque bond strength (kPa)

Conventional (UT) >250

Intermediate (IT) >500

Premium (PT) >1000

Note: The tabulated values are for guidance only - no correlation with the values in Table 2 is implied nor established.

Selection

4.4.9. Selection is dependent primarily on:

•

Substrate condition;

•

Surface thickness;

•

Surface type;

•

Site stress conditions.

4.4.10. Suggested grades of bond coat which are likely to be appropriate are presented in Table 4. These are grouped into three categories; conventional (U), intermediate (I) and premium (P).

4.4.11. For those surfaces which are covered by generic specifications and the site condition criterion indicates differing requirements for minimum bond coat, the highest overall grade should be selected.

4.4.12. For those surface systems which are proprietary in nature the BBA certification should take precedence but the authority should still evaluate the site against the condition criteria in Table 4. If this results in an anomaly with the proprietary proposals then it should be brought to the attention of the system proprietor.

Table 4 - Selection of Bond Coat

Condition

Recommended bond

coat

Substrate sound and

rugous

U

Substrate smooth /

polished

I

Substrate lacking

bitumen

P

Substrate slight

cracking

P

Surface thickness

30-40mm

20-30mm

<20mm

U

I

P

Site stress level

(NG942)

1

2

3

4

U

I

P

P

4.4.13. Bond coats should be spread at the rates in the BBA certification for proprietary systems or at the rates in BS 594 or BS 4987 for generic requirements as appropriate. There should be a continuous even spread without puddles of coating and the rate of spread should be regularly checked.

4.4.14. Spraying should not be too far in advance of the paving process and if there is any sign of picking up by delivery trucks the bond coat should be lightly gritted. Self-propelled sprayers or integral paver mounted spray bars should always be used where appropriate. When integral spray bars are used the bond coat formulation adopted should ensure virtual instant breaking of the emulsion. For the best quality of work and least traffic disruption integral spray bars applying intermediate or premium grade bond coat are preferred to other systems.

4.5.

Early Life Surface Characteristics

4.5.1. Previously much of the surfacing on the local network was of matrix dominated HRA type. This surfacing displays positive texture as chippings are embedded in the material to provide the skid resistant surface.

4.5.2. The film of bitumen which coated the chippings in the surface of HRA was very thin (circa 2 microns) and was generally unmodified residual petroleum bitumen. The passage of vehicle tyres removed this thin film rapidly due to the scrubbing effect of the constantly flexing tyres, the relative roughness of the surface and the positive texture encountered in resistance to rolling. The aggregate mineralogy of the chipping was exposed swiftly to deliver the in-service skid resistance.

4.5.3. Negative texture surfaces as provided by NTS are significantly different in their early life characteristics. There is less resistance to rolling due to the negative texture and the tyres do not impart the same scrubbing effect as the wheel travels forward. The tyres pass over the surface with only the vertical component of load having a wear effect.

4.5.4. The binder film is much thicker (circa 10 microns) for SMA negatively textured surface material. This results from the need to formulate the thin surfacing material as a whole to produce a stable mastic structure to support the mineral skeleton of aggregate. To enhance the binder stability and durability and to prevent binder drainage during transport, additives such as cellulose fibres or polymers are often used. These binder modifications result in a greater tenacity and adhesion between the binder and the mineral aggregate. With the combination of a thick binder film and the inclusion of modifiers, a substantially greater number of wheelovers are required to wear the binder film and expose the aggregate as the skid resistant surface.

4.5.5. Under the action of vehicle braking in an emergency on NTS, the thick binder film may be mobilised, either by melting or shearing. This plays an active role in effecting the maximum level of friction that can be generated between a locked and sliding tyre and pavement surface during the braking manoeuvre.

4.5.6. The early life dry skid resistance of asphalt surfaces (Roe and Lagarde-Forest, 2005) has confirmed that the phenomena can be attributed to the presence of a film of binder, that can adhere to the surface of aggregate particles for a significant period of time.

4.6.

Skid Resistance Characteristics

4.6.1. Until recently, almost all consideration of skid resistance in the maintenance of highways has been directed towards the investigation and routine monitoring, of frictional properties of the surfaces of wet, rather than dry, roads.

4.6.2. Skidding resistance survey requirements are described in the Code of Practice, (Section 9.8), which recommends that authorities should publish their skid resistance strategy as part of their Highway Asset Management Plan. The mechanisms and physics of skid resistance are complex. Vehicle tyre interaction with the surface is one of the key characteristics and beyond the scope of these Guidelines. Useful information and references are contained in the Code of Practice and also in the joint AA Motoring Trust / CSS publication on tyres, road surfaces and traffic accidents (Get a Grip, 2005 and Bullas, 2004). 4.6.3. For the purposes of erecting warning signs to alert road users to early

life skidding, the Code of Practice recommends that authorities should state in their skid resistance strategy that they should either:

•

Follow the requirements of Highways Agency Interim Advice Note 49/03; or

•

Produce an early life strategy that is generally based upon the requirements of IAN 49/03.

4.6.4. For NTS, once the early life stage has been passed and the binder film removed from the aggregate surface it would be anticipated that the material would provide a good period of service life before wear and polishing required future corrective maintenance. NTS materials generally contain a high proportion of coarse premium aggregate but the polishing resistance of the fine aggregate also plays a part in the skid resistance properties of the surface. Careful aggregate choice will ensure a long service life. Rather than remove and replace a worn or polished surface, consideration could be given to surface restorative techniques, to ensure that value for money is delivered from these premium mineral assets.

4.6.5. The removal of the relatively thick binder film from aggregate at the surface in NTS types of material will take time to occur. The two agencies which have an active role in this process are:

•

Vehicle tyres;

•

Environment.

4.6.6. Environmental ageing of the binder film will commence as soon as it is installed but this is a slow process of gradual embrittlement and is anticipated to have only a secondary influence in the removal of binder film in the shorter term.

4.6.7. The primary removal method is a physical one caused by the passage of vehicle tyres. If a particular type of NTS is used in a heavily trafficked situation, the binder film will be removed in a much shorter time than if the same material was used in a lightly trafficked situation. This has prospective implications for risk evaluation which must be undertaken in the selection of surface type on the network.

4.6.8. The early life period of trafficking could be much longer than on the strategic network because of the potentially lower density of traffic on the local network. The number of wheelovers necessary to remove the binder film remains the same irrespective of location and for local highways with lower traffic densities could take an extended time. The nature and thickness of the binder film introduces further complexity since differing types of NTS would be expected to display differing binder film thicknesses and also different binder types, such as unmodified bitumen, cellulose modified bitumen, polymer modified bitumen or cellulose / polymer modified bitumen. The relative wear rates and number of wheelovers to remove the binder film requires definition, in order that specifiers are better able to predict the duration of early life characteristics in various situations on their network.

4.6.9. In situations where a high friction surface is to be placed over NTS but the surface will be trafficked prior to the application of the high friction surface, then 3mm grit should be applied and rolled in to provide enhanced short-term skid resistance (HD37/99). The use of surface applied grit on NTS on the local network may also be appropriate to accelerate the removal of thick binder film in early life in those situations which are required to exceed a minimum skid resistance intervention level.

4.7.

Horses on the Highway

4.7.1. The particular friction characteristics of steel shod horses on thick binder film TS and SMA is described in guidance produced jointly by CSS and the British Horse Society entitled “Horses and Highway Surfacing: A Guidance Note for Highway Authorities”. (CSS, 2005). 4.7.2. The guidance includes recommendations for the application of grit

during the construction process at locally determined sites, which may include gradients, normal routes used by horse riders and roads adjacent to racecourses and riding stables.

4.8. Installation

4.8.1. The two key elements of successful long-term serviceability for surfacing comprise:

•

A sufficiently resilient substrate on which the surfacing is placed; and

•

A high standard of workmanship in the placement and compaction of the material.

4.8.2. Authorities who adopt a generic surfacing have direct control and responsibility for selection and specification of both bond/tack coat and also the component elements of the surfacing material. The substrate

will also have been evaluated by the authority to ensure that it is sufficiently competent for the required surface performance.

4.8.3. Proprietary TS systems, unless defined more closely in site specific requirements, require much more decision making by the system proprietor in terms of selection of options, within the scope of the BBA certificate relating to his system. The requirements and processes of BBA certification and client confidence expectations are presented in Appendix F.

4.8.4. Proprietary system installers have detailed methodologies and requirements relating to their system encapsulated within their Quality Plan which is held in confidence between the system proprietor and BBA. Protocols may be available for substrate evaluation as part of the system but the scope and extent of these is unlikely to be known. 4.8.5. Substrate resilience is a significant factor in terms of strain

compatibility and integral performance with the characteristics of the installed surface. Substrate evaluation should be undertaken through objectively defined limits and properties, together with identification of any flaws which require remedial works prior to surfacing installation. 4.8.6. Once an appropriate test method has been determined to characterise

flexibility of NTS, and other traditional surface materials, the compatibility of this with the substrate flexibility, perhaps determined by deflection devices, will enable more refined selection. At present, however, these processes are not developed and may not be so for some time in the future.

4.8.7. To provide clarity of engineering performance, greater transparency of the decision making process relating to substrate condition would be beneficial. It is assumed that objective inspection and condition data already exists within proprietary system installer organisations. This data is of value both in maximising the long-term performance of materials and in highlighting likely areas of future distress, both of which will ultimately provide better prediction of serviceability for risk and asset management planning.

4.8.8. The best surface is only as good as its weakest elements and for most NTS it is the edges, ends of loads, tie-ins, longitudinal joints between adjacent paver rips and transverse construction day joints. Successful and durable joints can only be formed whilst the material is hot or sawn and the vertical face fully coated with bitumen. If the formation of joints is not undertaken to a high standard then the joint interface can become a focus for the commencement of fretting under trafficking. This can lead to premature distress in an otherwise serviceable surface.

4.8.9. The location, position and pattern of joints in highly stressed areas require particular consideration in relation to vehicle wheel paths, where there may be lateral loading effects. Saw cut slots for induction loops in NTS at traffic light approaches can also be a focus for initiation of fretting. The avoidance of dynamic impact loading from heavy goods vehicles, especially on thinner surfaces, can be addressed through ensuring evenness of the surface during installation and the setting of ironwork at finished road surface level.

4.9.

Installers and Inspection

4.9.1. The views and observations of a cross section of installers relating to substrate conditions, materials selection, client role, placement and other key issues are presented in Appendix I.

4.9.2. It is good practice for every site to be inspected by experienced and knowledgeable personnel. In situations where a generic specification is used for the surface, any potential adverse interaction of the chosen surface with the substrate is a risk for the authority. For proprietary surface systems a joint inspection by the authority and the system proprietor has merit in highlighting awareness of substrate characteristics and improving the performance prediction of the selected proprietary surface system.

4.10. References

1. Kennedy. CK and Lister, NW. (1978). “Prediction of Pavement Performance and the Design of Overlays”, TRRL Report LR833, TRL Ltd, Crowthorne. ISSN 0305-1293.

2. Roe, PG and Lagarde-Forest. R (2005). “The early Life Skid Resistance of Asphalt Surfaces”. Report PPR060, TRL Ltd, Crowthorne.

3. CSS (2005). “Horses and Highway Surfacing”. Guidance Note,

www.cssnet.org.uk .

4. The AA Motoring Trust/CSS (2005) “Get a Grip”. www.AAtrust.com

or www.cssnet.org.uk .

5. Bullas. JC. (2005), “Tyres, Road Surfaces and Reducing Accidents: a review”. www.AAtrust.com

4.11. Summary

•

NTS performance was found to be as good as traditional materials except in some specific areas and applications.

•

The substrate plays a key role in the overall pavement serviceability.

•

Adhesive bond between the surface and the substrate was identified as a key performance parameter and a bond coat selection process has been developed.

•

The survey indicated that there was almost equal procurement of surfacing by authorities using generic specifications as there was with proprietary systems specifications.

•

The local network has evolved over time and is often maintained in a state of limiting equilibrium. It is relatively thin and variable in terms of construction materials. This contrasts with the case of an engineered, stable, long life pavement.

•

The influence of water and porosity were identified as key aspects in terms of performance.

•

The essence of good performance is attributed to the installation of a strain compatible surface, which acts in concert with the intrinsic flexing movements of a thin pavement.

•

Overlay should be considered as the first choice option for surfacing owing to potential structural contribution but where inlay is

necessary the milling processes must be such that there are no remnants of weak existing materials.

•

Attention to detail in the location and formation of joints especially in highly stressed areas, will avoid premature distress in an otherwise serviceable surface.

•

Early life characteristics are described in terms of binder film thickness and removal by vehicle wheelovers. An assessment should be undertaken to determine the approximate length of time it will take to remove the binder film by traffic, based upon a forecast of numbers of wheelovers likely to be applied on a particular highway.

•

Guidance has been published elsewhere in respect of TS and SMA for areas where equestrians may use the network and recommends the use of grit applied to the freshly laid surface, to enable more rapid abrasion of the thick binder film.

•

For generic style specifications the risk for serviceability resides with the client organisation. For proprietary systems there is benefit in joint site inspections by the client and system proprietor to ensure that the most appropriate TS system is selected and installed.

5 THE RIGHT MATERIAL FOR

THE RIGHT SITE

5.1. Site

Evaluation

5.1.1. The evaluation of an existing site comprises the use of a checklist and four decision charts A to D inclusive.

5.1.2. The initial step in the evaluation process is to collate all of the available data relating to the site and to undertake a walk through inspection by experienced personnel. The walk through inspection will enable collection of all of the condition information necessary to use the decision charts. A checklist of details to be collected and assembled is presented in Table 5 and comprises:

•

Geometry and layout;

•

Traffic;

•

Road function;

•

Condition;

•

Road surface;

•

Data availability.

5.1.3. Four decision charts compliment the checklist and provide route maps for evaluation of the existing site conditions.

Site Checklist for NTS Road No:

Location:

Aspect Details (for completion) Considerations

Geometry and Layout

Road type Dual, single.

Situation Urban, rural.

Junctions or crossings Frequency , type, etc

Exposed site Yes/No

Gradient Flat, level, gentle, steep.

Direction facing North, south, east or west

Bend Yes/No

Roundabout Yes/No

Road closure possible Yes/No

Traffic

Speed limit 20, 30, 40, 50, 60, 70 mph

Braking area Yes/No

Accelerating area Yes/No

Turning - Bends Gentle, acute, etc

Turning - Roundabout Radius: tight/int./gentle.

Commercial vehicles High, medium, low

Reduced spray required Yes/No

Reduced noise required Yes(+40mph)/No

Road Functional Hierarchy

CoP function category 1, 2, 3a, 3b, 4a, 4b

Conditions

Surface drainage Good/fair, falls, gullies, etc

Highway drainage Ditch, filter drain, etc

Site prone to flooding Yes/No

Edge restraint Good (kerb/strip)/Poor

Restriction on overlay. Thresholds, access, etc

Restriction on inlay Practicality, etc

Existing Road Surface

Walk through inspection Yes(date)/No(reason)

Surface material HRA, DBM, NTS,etc

Oxidised Yes/No

Fretting Yes (severity)/ No

Cracking - longitudinal Yes (severity)/ No

Cracking – map (craze) Yes (severity)/ No

Cracking - transverse Yes (severity)/ No

Texture Good, average, poor

Rutting Yes (severity)/ No

Delamination Yes/No

Damp or wet areas Yes/No

Subsidence areas Yes/No

Condition Data availability

CVI Yes/No

DVI Yes/No

Core records Yes/No

Exploratory pit records Yes/No

Deflectograph survey Yes/No

FWD survey Yes/No

Ground penetrating radar Yes/No