The objective of Boston’s Central Artery/Tunnel (CA/T) Project is to ease the congestion of approximately 190,000 vehicles per day traveling through the city of Boston. This objective is being achieved through the total reconstruction of Interstate Highway I-93 as it passes through the heart of Boston, together with the extension of Interstate I-90 from its terminus at I-93 just south of downtown Boston to Logan International Airport in East Boston. The Artery replaces an elevated six-lane highway that opened in the late 1950s and originally carried approximately 75,000 vehicles per day. The focus of this article is on two transition structures and ramps in the C09C2 Construction Contract: the I-93/I-90 Interchange Ramps and Surface Restoration at Albany Street, where shot-crete facing has been implemented as a facing system for lightweight embankments.
Steel Fibrous Shotcrete: A Summary of the State-of-the-Art
Steel fibrous shotcrete has been used for mine and tunnel linings, for rock slope stabilization, in dam construction, for repair deteriorated surfaces and arches, for fire protection coatings and in thin-shell dome construction.
Release of New ASTM Round Panel Test
Following a 3-year development period, a new test for post-crack performance assessment of ï¬ber-reinforced shotcrete (FRS) and ï¬ber-reinforced concrete (FRC) based on round panels was passed by ASTM Committee C 09 in June 2002. The standard test method, known as C 1550-02, œStandard Test Method for Flexural Toughness of Fiber-Reinforced Concrete (Using Centrally-Loaded Round Panel), was published in the 2002 edition of the Annual Book of ASTM Standards V. 4.02.1 Publication of this standard test method is a major development in the fiber-reinforced shotcrete industry. It will, for the ï¬rst time, permit a both reliable and economical estimation of post-cracking performance for this material.
The use of ï¬bers in shotcrete has become an established form of reinforcement in many sectors of the underground construction industry over the last 20 years. The effective measurement of post-crack performance (toughness) in this material, however, is a problem that has plagued the industry and made the influence of parameters such as ï¬ber type, mixture design, and spraying technique difï¬cult to determine. Much of the difï¬culty is attributable to the high levels of within-batch variability obtained for even well-prepared sets of FRS samples when beams are used as the basis of toughness assessment. Typical levels of within-batch variability for toughness indices obtained using ASTM C 1018 beams range from 13 to 18%.2,3 More than18% is common for residual strength obtained using EFNARC beams.4 The imprecision associated with such high levels of variability has obscured trends in performance development and eroded conï¬dence in the material. Some improvement occurred with the introduction of EFNARC panels in the 1990s,5,6 but this test suffered its own difï¬culties associated with seating problems and high costs. Other types of specimens have seen occasional use,7-10 but the size and expense of these tests have limited their use to special applications.
The ï¬rst round panel test similar to the C 1550 conï¬guration was undertaken in 1997 as part of an investigation of the influence of support conditions on structural behavior in FRC panels.11 The potential of this test was recognized by the Roads and Traffic Authority of New South Wales in Australia, which immediately sponsored a comparative study of FRS performance for several commonly available ï¬bers.12 A speciï¬-cation based on this test13 was also introduced
Shotcreting in Australian Underground Mines: A Decade of Rapid Improvement
Over the last decade, dramatic improvements in spraying technology have allowed shot-crete to become the first-choice ground support in many underground mines in Australia. Before 1994, only a very small amount of dry spray shotcrete was used. Since then, the increased use of wet-mix ï¬ber-reinforced shotcrete has been extremely rapid, spurred along by improvements in machinery, admixtures, fibers, and under-standing the way shotcrete behaves as a ground support element.
Today, nearly 100,000 m3 (130,000 yd3) of shotcrete is applied annually in some 20 under-ground mines. While volumes have leveled off during a recent period of depressed metal prices, it is almost certain to boom again as metal prices improve and new mines come online. Australian mines are characterized by reasonably shallow ore bodies hosted in hard rock. This made under-ground mining initially fairly simple with little ground support needed beyond a few rock bolts. As surface deposits have become depleted, however, mine owners are increasingly spending their exploration dollars drilling beneath existing deposits to ï¬nd new resources. This has led to ever-deepening extraction depths and associated ground support difï¬culties.
Determination of Early-Age Ductility of Steel Fiber-Reinforced Shotcrete Lining System at INCO’s Stobie Mine
The state of technology in shotcrete materials has evolved steadily throughout the world and particularly in North America during the last 20 years. The use of supplementary cementing materials such as silica fume, fly ash and slag, the new generations of chemical admixtures, and the development of various types of ï¬bers (steel and synthetic) signiï¬cantly enhance the performance of shotcrete for a variety of applications.
These technological advancements have led the international mining industry to become a major user of shotcrete for underground support. Because the potential for instability in underground rock openings is a threat to the safety of miners, the support of permanent openings in underground mining is a critical area of shotcrete application. For over 20 years, mining companies have recog-nized the value of steel ï¬ber reinforcement in shotcrete. It has been proven that the performance of steel fiber-reinforced shotcrete compares favorably with steel-welded wire mesh reinforced shotcrete in various ground support applications.1
The introduction of steel ï¬bers in shotcrete increases its energy absorption or œtoughness, increases impact resistance, and provides increased ductility. Ductility is defined as the ability to continue to carry loads after the shotcrete micro-structure has cracked. These mechanical properties are considered extremely important parameters with respect to support linings designed for the underground environment.2 (The effects of addition rate, geometry, and property of ï¬bers are beyond the scope of this article.)
Although the ability of steel ï¬ber-reinforced shotcrete to carry loads in flexure beyond its flexural capacity can be assessed in laboratories using a variety of beam and panel test methods, the under-standing of how to relate it to ground support design guidelines for underground mine devel-opment is limited and subjective.3
Test methods evaluating the load-carrying capacity of steel ï¬ber-reinforced shotcrete (SFRS) performed after 7 and 28 days of curing do not assess
Combining Shotcrete Mixes for Maximum Performance
Rebound is an essential element in the application of shotcrete. Rebound is deï¬ned as follows: œMainly large aggregate with some sand and cement that bounces or ricochets off the receiving surface and falls on to lower surfaces.1 There is a vital function that is achieved in the rebounding of shotcrete. The secret lies in knowing how much rebound is enough.
To paint a mental picture for the reader to understand rebound, consider a baseball. If you take a baseball and dip it into some fresh concrete and pull it out, it will be covered with mortar”a paste consisting of the cement and ï¬ne aggregate and water”that acts as the glue required to create an artiï¬cial rock called œconcrete. If you took this baseball covered with mortar and threw it at a high velocity against a solid block wall at a 90-degree angle to the wall, the ball would strike the surface and bounce off. Because the paste is also in motion at 95 miles per hour and the paste is not securely bonded to the ball, some paste will leave the surface of the baseball, contact the wall, and adhere to the surface. In layman™s terms, it would œsplat onto the wall. The harder the baseball is thrown, the more the paste would leave the surface of the
Is Computerized Shotcreting a Possibility? It’s a Reality!
A nozzleman who has made a transition from hand-nozzling to using a robotic arm knows the value that mechanical technology has brought to our industry. Far beyond just saving human backs and arms during a shift of spraying concrete, robotic arms (booms, lances, etc.) have taken the application of shotcrete to the next level, facilitating rapid deployment of material to signiï¬cant thicknesses, in hard-to-reach areas, particularly in underground construction environments (tunnels or mines).
This quantum leap in technology, while requiring training and skill to operate, makes shotcreting easier.
But what if those human factors that detract from the quality of in-place shotcrete could be controlled or eliminated? With the use of emerging technology, human error can be reduced or even eliminated.
Shotcrete for Ground Support: Current Practices in Western Canada
Historically, in Western Canada, the stabilization of rock slopes and construction of excavations have been achieved using methods such as soldier piles and lagging or construction of cast-in-place concrete retaining walls. In the case of reinforced cast-in-place concrete, there is a requirement for erection of formwork, fixing of reinforcement, pouring the concrete mixture, and vibration to ensure good concrete consolidation and steel encapsulation. These methods have proven to be relatively ineffi-cient and costly in many cases. In recent decades, however, the use of shotcrete for ground support has seen increased use, as shotcrete has allowed
The Art of Tunnel Rehabilitation with Shotcrete
The art of rehabilitation of tunnels has flourished and developed significantly over the last couple of decades. Several hundred railroad, highway, and conveyance tunnels have been successfully rehabilitated, converted, and/or enlarged. Much of this development can be attributed to the successful use of steel fiber-reinforced shotcrete. The flexibility and adaptable nature of steel-fiber microsilica shotcrete is ideal for rehabilitation of tunnels. Thanks to shotcrete, enlargement and rehabilitation of tunnels without fully taking the tunnel out of service is not only technically but also economically feasible consid-ering the cost of other alternatives including the œdo nothing alternative. Enlargement was usually accomplished by raising the crown but some have been enlarged by lowering the invert, which is much more difficult and time-consuming.
Shotcrete in Fires: Effects of Fibers on Explosive Spalling
In those of us in the concrete industry, the events over the last year have caused many of us to focus on the effects of blasts and fire on concrete structures. Information on the effects of fire on normal strength concrete (NSC) less than 7000 psi (50 MPa) has been available since the 1950s.1 On the other hand, little information on the behavior of high-strength or high-performance concrete (HPC) in fires has been developed until recent times, particularly with reference to thermal shock (high temperature rise rates) and sustained high temperatures.2