Design Mixes For Asphalt Using 1-Inch And 1/2-Inch Steel Slag

Building Technology | Civil Engineering | Engineering

Designing asphalt mixes using 1-inch and 1/2-inch steel slag aggregates involves carefully selecting proportions to achieve optimal performance and durability. Steel slag, a byproduct of steel manufacturing, offers benefits such as improved stability, durability, and resistance to rutting and moisture damage compared to traditional aggregates. To create a robust mix, engineers typically conduct laboratory tests to determine the optimum blend of steel slag, asphalt binder, and other additives like mineral fillers and rejuvenators. The mix design process involves adjusting aggregate gradation, asphalt binder content, and compaction parameters to meet specified performance requirements for the intended application, whether it be high-traffic highways or low-traffic roads. Utilizing advanced testing methods and computational tools, engineers can tailor the mix to enhance fatigue resistance, reduce permeability, and ensure long-term performance, ultimately contributing to sustainable and cost-effective pavement solutions.

ABSTRACT

Asphalt concrete can be produced and the pavement constructed readily in Oregon when crushed steel slag is used as a portion of the aggregate. If the unit cost of steel slag modified mixes is the same as conventional dense graded mixes, overall project costs may increase because of the decrease in coverage by the heavier steel slag mix. For the test section hot mix asphalt concrete (HMAC) constructed with 30% steel slag, the coverage was 15% less than a conventional “B” mix. Reported increased resistance to rutting and improved skid resistance was not measured during the five years the pavements have been monitored. The differences between the two sections may not be measurable because only 30% steel slag with dimension of 1-inch (25.4 mm) … 1/2–inch (12.7 mm) was used in the test mix and the slag was finer than the conventional ½ – ¼” (12.7 to 6.3 mm) material it replaced. To date, both the control and test sections are performing satisfactorily.

TABLE OF CONTENTS

COVER PAGE

TITLE PAGE

APPROVAL PAGE

DEDICATION

ACKNOWLEDGEMENT

ABSTRACT

CHAPTER ONE

INTRODUCTION

1.1 BACKGROUND OF THE PROJECT

OBJECTIVE OF THE PROJECT
SCOPE AND SIGNIFICANT OF THE PROJECT
BENEFIT OF THE PROJECT
PROJECT ORGANISATION

CHAPTER TWO

LITERATURE REVIEW

OVERVIEW OF STEEL SLAG
OVERVIEW OF STEEL SLAG
BASIC OXYGEN FURNACE SLAG
SECONDARY SLAGS
STEEL SLAG PRODUCTION
DOMESTIC PRODUCTION
WORLD STEEL PRODUCTION
CURRENT USES AND APPLICATIONS

CHAPTER THREE

METHODOLOGY

DESIGN
MATERIALS

CHAPTER FOUR

RESULT ANALYSIS

TEST RESULTS
MIX DESIGNS
CONSTRUCTION
MIXING
PLACEMENT AND COMPACTION
FIELD MIX PROPERTIES
POST CONSTRUCTION EVALUATION
FIELD INSPECTIONS
SKID TESTING
RIDE TESTING
PERFORMANCE SUMMARY

CHAPTER FIVE

CONCLUSION
RECOMMENDATION

CHAPTER ONE

1.0 INTRODUCTION

1.1 BACKGROUND OF THE STUDY

In September 1994, steel slag test and control sections were constructed in Oregon to evaluate the use of steel slag in hot mix asphalt concrete (HMAC). Steel slag, a by-product of the steel- making process, is readily available in the Portland Metropolitan area. If unused, the slag material could end up in landfills, costing Oregon taxpayers money as disposal facilities reach capacity and new landfills are required. One way to utilize the steel slag is to incorporate it into hot mix asphalt concrete (HMAC). This process has been used successfully in the midwest and eastern United States with reported improved pavement performance (Ramirez 1992). Prior to this study, Oregon had no experience in handling, testing, or constructing steel slag pavements.

1.2 OBJECTIVES OF THE PROJECT

The primary objective of this study is to evaluate the use of steel slag in hot mix asphalt concrete. All aspects of using this material in a pavement will be evaluated, including:

Steel slag sampling methods and laboratory tests,
Asphalt concrete mix design and testing,
Constructability, and
Performance

Other objectives include determining appropriate revisions to mix design procedures for the addition of steel slag.

1.3 SCOPE AND SIGNIFICANCE OF WORK

Steel slag has been used to construct pavements for nearly one hundred years. Since it was discovered that the residue from the manufacture of steel could be crushed and processed into a product that looked like crushed rock, other testing was performed to determine the usefulness of this “waste” product.

It was discovered that the highly angular, rough textured, vesicular, pitted surfaces provide the particle interlock, and if properly compacted, the high stability required for good serviceable pavements. The slag is usually added as part of the coarse aggregate fraction of the mixture at a percentage of 20% to 100%, depending on the application of the mixture.

Addition of steel slag may enhance the performance characteristics of the pavement. Since the slag is rough, the material improves the skid resistance of the pavement. Also, because of the high specific gravity and angular, interlocking features of the crushed steel slag, the resulting HMAC is more stable and resistant to rutting (Ramirez 1992, Noureldin and McDaniel 1990, Lemass 1992).

Currently there are two steel mills producing steel slag in Oregon, both in the Portland area: Cascade and Oregon Steel. Cascade currently produces about 60,000 to 70,000 tons/year (54,000 to 63,000 Mg/year) of steel slag. Oregon Steel produces about 100,000 tons/year (90,000 Mg), and currently has about 300,000 tons (270,000 Mg) on hand. This slag would normally be placed in a landfill if it was not crushed and used for construction material.

1.4 BENEFITS OF THE PROJECT

Steel slag may be an appropriate addition to asphalt concrete. The current specifications do not exclude the use of steel slag. The overall benefit of the research will be an understanding of the properties of steel slag hot mix asphalt concrete and the applicability to future projects.

Typical aggregate used for HMAC in the Portland area includes crushed gravel. Pavements with the crushed gravel are typically not as stable as mixes without gravel and are often susceptible to rutting. The addition of steel slag may provide a viable alternative to the crushed gravel, as it reportedly increases the stability of the mix materials, thus reducing the rutting potential.

If steel slag used as an aggregate is determined to be an appropriate addition with benefits to asphalt concrete, then additional HMAC pavements may be constructed with steel slag. The agency may also encourage the use of steel slag in some pavements by providing incentives.

Other benefits of using steel slag in asphalt concrete include the recycling of a waste product, thus reducing the volume of material placed in Oregon landfills.

1.5 PROJECT ORGANISATION

The work is organized as follows: chapter one discuses the introductory part of the work, chapter two presents the literature review of the study, chapter three describes the methods applied, chapter four discusses the results of the work, chapter five summarizes the research outcomes and the recommendations.

CHAPTER FIVE

5.1 CONCLUSIONS

Asphalt concrete can be produced and the pavement constructed readily when crushed steel slag is used as a portion of the aggregate. If the unit cost of steel slag modified mixes is the same as conventional dense graded mixes, overall project costs may increase because of the decrease in coverage by the heavier steel slag mix. For the test section of HMAC constructed with 30% steel slag, the coverage was 15% less than a conventional “B” mix. Reported increased resistance to rutting and improved skid resistance was not measured during the five years the pavements have been monitored. The differences between the two sections may not be measurable because only 30% steel slag was used in the test mix and the slag was finer than the conventional ½- to 1-inch (12.7 – 25.4 mm) material it replaced. To date, both the control and test sections are performing satisfactorily.

Considerations for future use of steel slag in HMAC:

The gradation of the steel slag should be monitored to assure that a uniform mixture of hot mix is produced.
Specific gravity of the produced slag aggregate should be monitored. As a rule, as the slag particle size increases, the specific gravity
More energy is needed to heat the slag mix to a given temperature than conventional aggregate, however, the mix holds the heat longer and therefore cools
A specification will need to be developed that addresses the use of steel slag as an aggregate.

5.2 RECOMMENDATIONS

No changes to the current asphalt pavement specification are
Additional mixes should be evaluated using the Superpave mix design system. Superpave may allow for optimizing the gradation and also better determine the asphalt demand. It is also recommended that the slag be crushed to meet a specific designated size gradation, such as ¾” – ½”, ½” – ¼”, or ¾” – ¼” (19 – 12.7 mm, 12.7 – 6.3 mm, 19 – 6.3 mm) and/or replace the entire portion of coarse aggregate with crushed
It is recommended that two or three more test sections be constructed with aggregates that generally produce mixtures with marginal stability, to determine if the slag blend would in fact improve this
The economics for future use, as a supplement for potential increases in stability should be evaluated on an as needed basis. Considerations such as increased aggregate weights, increased mixing temperatures and reduced HMAC coverage may make steel slag cost prohibitive.