Advantages of Steel Fiber

27 Nov.,2024

 

Advantages of Steel Fiber

Do you want to build your dream home or office? Or do you have a next construction project? Every construction takes a big part of your fortune; therefore, you should opt for something durable that boosts the worth of your money and effort. There are so many options available to get the desired strength but using fiber reinforced concrete (SFRC) is now one of the widely used options. It is a mixture of discontinuous and discrete steel fiber and concrete.

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The use of steel fiber increases the strength of concrete, so any environmental and weather change cannot influence its durability. Moreover, concrete with steel fiber ensures the safety of your loved ones. Also, you can save project costs and time.

However, choosing a trustable steel fiber supplier is important to get what you look for. Many brands work as steel fiber sellers, but Forcetech is one of the highest customer trusted options because of their cutting edge technologies and customer support. You can contact them 24/7 for information and guidance.

Advantages of Steel Fibers in Concrete

Steel fiber in concrete improves the compressive and shear strength of concrete to a greater extent. This is possible as steel fiber saves concrete from cracks and increases its weight-bearing power. Also, it reduces the shrinkage and concrete with steel fiber makes the mixture tough and provides micro-cracks protection. Following are some of the significant benefits of steel fiber reinforced concrete.

  • Because of the reduction in cracks and boost in weight-bearing power, buildings with steel fiber reinforced concrete needs low maintenance, which later saves money.
  • With the right amount of steel fiber, you get the concrete without permeability, dusting, or breakage signs.
  • It saves money, as with steel fiber; you don&#;t need a thick concrete slab.
  • You have to pay less for chemicals as water as steel fiber reduces the absorption capacity of concrete.
  • An overall low project cost as you required low labour when dealing with steel fiber reinforced concrete.
  • Steel fiber gives you a rigid concrete surface with no chances of holes and leakage.
  • Steel fiber reinforced concrete can be your best companion if you need something to make joints with convenient positioning.
  • Improve flexural strength, which is even higher than the concrete one.

Tips to Improve Strength of Concrete with Steel Fiber

  • As steel fiber boosts the pressure-bearing power of concrete and keeps it crack-free. However, it is only possible when you mix steel fiber properly. So before use, give steel fiber and concrete an excellent mix to get desired results.
  • Use arranged fibers mix technique to improve concrete strength as the random mix cannot fulfill strength requirements.
  • Make sure to consider factors such as aspect ratio, fiber volume, fiber orientation, and mixing before making the SFRC, as these are determinants of results.

The Verdict

Steel fiber reinforced concrete is a widely accepted option for durable construction because of its unlimited applications and mechanical properties. Having steel fiber in an appropriate amount with an adequately arranged fiber mix can boost the durability and strength of concrete. If you want the desired results, choose the right type of steel fiber from a well-known company like Foretech. Choose the best for you wisely, as adding this to your next construction project saves money, time, and labour.

 

Specifying steel fibers for concrete floors

by George Garber
Thin, short strands of steel fiber are being specified more and more as reinforcement in concrete floors. Sometimes, these fibers are used on their own, and sometimes they are used in conjunction with conventional reinforcing steel. They appear in ground-supported slabs and in composite steel deck slabs.

In ground-supported slabs they are used to control cracks, to allow greater joint spacing, and to justify thinner slabs&#;though the last goal is controversial because it involves properties of fiber-reinforced concrete that experts disagree on. In composite steel deck-slabs, fibers can replace traditional wire mesh to control shrinkage cracks.

Structural engineers are still figuring out how best to design floors with steel fibers. American Concrete Institute (ACI) 360R-10, Guide to Design of Slabs-on-ground, offers guidance on their use in ground-supported floors. Steel Deck Institute (SDI) C-, Standard for Composite Steel Floor Deck&#;Slabs, gives basic rules for using them in composite steel decks. However, neither document represents the last word on the subject, so the research continues. Meanwhile, specifiers need to think about how to define this material in contract documents.

Whenever people learn a job will include steel fibers, the first question is always some variant of &#;how much?&#; It seems everyone wants to know the fiber dosage, which is usually stated as the mass added to each unit volume of concrete. Typical units are kilograms per cubic meter (kg/m3) or pounds per cubic yard (lb/cy).

Dosage matters, of course, but it is just a start, because not all fibers are alike. If other key details are not specified, the result is concrete that contains the specified mass of fibers, but does not fulfill the designer&#;s intentions.

Steel fibers in specifications
Since steel fibers can be considered a kind of reinforcement, it is tempting to stick them in MasterFormat Division 03 20 00&#;Concrete Reinforcing, with rebar and wire mesh. However, fibers are better handled in Division 03 30 00&#;Cast-in-place Reinforcing or Division 03 24 00&#;Fibrous Reinforcing. If fibers are put in their own section, it should be referred to in Division 03 30 00&#;Cast-in-place Concrete as this is where the concrete contractor and ready-mix supplier will look. If the specifications include a special section for the concrete floor, then that would be a good place for the steel fibers.

Every steel-fiber specification should incorporate, by reference, ASTM A820, Standard Specification for Steel Fibers for Fiber-reinforced Concrete. This document lays down rules for strength, bendability, dimensional tolerances, and testing that apply to all kinds of steel fibers commonly used in concrete floors. Fibers must have an average tensile strength of at least 345 MPa (50,000 psi). They must be flexible enough to be bent 90 degrees around a 3-mm (1/8-in.) rod without breaking. They cannot vary from specified length or diameter by more than 10 percent. (This does not need to be put in the project specifications, because ASTM A820 does the work for you.)

ASTM C, Standard Specification for Fiber-reinforced Concrete, can also be incorporated into specifications. This standard regulates how fibers are added to the concrete mix.

Citing ASTM A820 and ASTM C is never enough, however, as these standards explicitly leave important decisions to the designer. A complete specification covers all these points:

  • dosage;
  • type;
  • length;
  • effective diameter or aspect ratio; and
  • deformations.

 

 

 

 

 

 

 

 

Fiber dosage
The amount of fiber is usually specified by mass of fibers per unit volume of concrete&#;this is measured in kg/m3 or lb/cy. An alternative is to specify the fiber volume as a percentage of the concrete volume. This makes a lot of sense, especially during the design stage. A volume percentage is easier to visualize, and it stays the same across all measurement systems. However, the workers who actually put the fibers in the concrete have no way to batch by volume. They can only batch by mass, so any volume-based specification will have to be converted along the way. Figure 1 shows equivalents for some specified dosages.

Fiber dosages generally range from 12 to 42 kg/m3 (20 to 70 lb/cy). Dosages below that range are occasionally specified when fibers are used to replace light-gauge wire mesh. Dosages above that range are rare.

Setting fiber dosage is not an exact science, but ACI and SDI offer guidelines. According to ACI&#;s Guide to Design of Slabs-on-ground, the fiber dosage in ground-supported slabs should never be less than 20 kg/m3 (33 lb/cy). When the purpose of the fibers is to allow a wider joint spacing, this guide recommends at least 36 kg/m3 (60 lb/cy). SDI&#;s Standard for Composite Steel Floor Deck&#;Slabs, has a short, simple recommendation for steel fibers in composite steel deck-slabs: use at least 15 kg/m3 (25 lb/cy). In the end, though, the decision is up to the floor designer, who may rely on experience or on recommendations from one of the steel-fiber manufacturers.

Types
ASTM A820 divides steel fibers into five types, based on how they are made:

  • Type I&#;cold-drawn wire;
  • Type II&#;cut-sheet steel;
  • Type III&#;melt extract;
  • Type IV&#;mill cut; and
  • Type V&#;cold-drawn wire, shaved into fibers.

Only Types I, II, and V are currently being used in concrete floors.

Predictably, fiber manufacturers disagree on which type works best. From the user&#;s point of view, the main issue is certain properties may not be available in all types. For example, in the current market the only fibers being made with hooked ends are Type I.

When discussing fiber type, one must watch out for confusion between ASTM A820 and ASTM C. ASTM A820, which deals only with steel fibers, divides them into the five types listed above. In contrast, ASTM C, which deals with all kinds of fibers, divides fiber-reinforced concretes into four types, depending on what kind of fibers they contain. In ASTM C, concrete with steel fibers is called Type I. Types II, III, and IV contain glass, plastic, and cellulose, respectively.

Thanks to the two different classifications, one can end up with a Type I concrete mix that contains, say, Type II steel fibers. It is important to remember the classification in ASTM A820 covers fibers, while the classification in ASTM C covers concrete mixes.

Contact us to discuss your requirements of Steel Fiber Manufacturer. Our experienced sales team can help you identify the options that best suit your needs.

Fiber length
The steel fibers used in concrete floors range in length from 25 to 65 mm (1 to 2 1/2 in.).

While it is usually agreed length matters, there is no consensus as to which length is best. It depends on what the fibers are expected to do. Engineers who rely on fibers&#; ability to limit the widening of cracks after they have formed&#;a property called residual strength, ductility, or flexural toughness&#;tend to prefer longer fibers. Those who rely on fibers&#; ability to prevent visible cracks tend to prefer shorter ones, because they result in higher fiber counts and less distance between fibers. Concrete workers also like shorter fibers, which are less likely to tangle and stick up above the floor surface.

There are limits in both directions, however. The upper limit seems to be close to 65 mm, and any longer will clump to form balls. Even fibers in the 50 to 65-mm (2 to 2.5 in.) range can tangle, and to prevent that problem are sometimes sold in collated form&#;stuck together with a weak glue that dissolves as the concrete is mixed. The lower limit has not been well-established, but fibers less than 25 mm long are seldom used in concrete floors today. Researchers are working with even shorter fibers, though, so floor designs that rely on lengths below 25 mm may be seen eventually.

If a design is based on fibers of a particular length, the specification should require that length. Length is specified as a single target value (not a maximum or minimum), with an implied tolerance, according to ASTM A820, of ±10 percent.

Effective diameter or aspect ratio
For a fiber with a circular cross-section, the effective diameter is that of the circular section. For a fiber with a cross-section of any other shape, the effective diameter is that of a circle equal in area to the actual section.

For fibers of Types I to IV, the effective diameter is specified as a single target number, with an implied tolerance of ±10 percent. Type II fibers, which are rectangular in section, can be specified by width and thickness instead of effective diameter. Type V fibers are supposed to be specified differently. Since the manufacturing process for Type V results in substantial variation in effective diameter, ASTM A820 suggests specifying a range with upper and lower limits, not a target. However, this rule is not universally followed. Some makers quote a single effective diameter for their Type V fibers.

People sometimes talk about a fiber&#;s aspect ratio instead of, or in addition to, its effective diameter. Aspect ratio is length divided by effective diameter. Since any two of those properties determine the third; all three do not need to be specified. When aspect ratio is specified, be aware ASTM A820 allows the measured value to vary by ±15 percent from the specified target.

In today&#;s marketplace, effective diameters range from 0.58 to 1.14 mm (20 to 40 mils). As with length, choosing the diameter involves trade-offs. Thicker fibers are less likely to tangle while thinner result in higher fiber counts.

Fiber count
Fiber count&#;the number of fibers per pound or kilogram&#;is an important factor in the effectiveness of steel fibers as concrete reinforcement. Higher counts result in less distance between fibers, and that generally means better performance. A floor design based on a particular fiber count may not work as well with a lower count, even if the mass of fibers stays the same.

Though fiber count is never directly specified, it is determined by two properties that are specified: length and effective diameter (or length and aspect ratio, depending on preference). Since shorter fibers are usually thinner, too, reducing the length dramatically raises the fiber count. In this figure, both piles have the same mass. The fibers on the right are 50 mm (2 in.) long and have an effective diameter of 1.14 mm (0.04 in.). The fibers on the left are 25 mm (1 in.) long and have an effective diameter of 0.58 mm (0.02 in.). The shorter fibers outnumber the longer fibers, almost eight to one.

Fiber count can be determined from the following equations:

In metric units:

c = 1/[(7.9 x 10-6)L?(d/2)2]

Where c = fiber count per kilogram
L = length of fiber in millimeters
d = effective diameter of fiber in millimeters

In U.S. customary units:

c = 1/[(0.29L?(d/2)2]

Where c = fiber count per pound
L = length of fiber in inches
d = effective diameter of fiber in inches

Fiber counts range from about to 20,000 per kilogram ( to per pound).

Deformations
The earliest steel fibers were smooth, straight pins, and ASTM A820 still recognizes that shape as an option. In practice, though, the fibers used today are all deformed so concrete can grip them better. Deformations take one of three forms: continuous, hooked ends, and flat ends.

A continuously deformed fiber has waves or bumps running down its whole length, much like ordinary steel rebar. A hooked-end fiber has a bend&#;or multiple bends&#;at each end. A flat-end fiber has its ends squashed flat, somewhat like a kayaker&#;s double-ended paddle.

Conclusion
While dosage, length, effective diameter, and deformation are the essential features every steel-fiber specification should cover, a few other details are worth considering.

Consider requiring fibers be delivered in containers marked to show the mass. Some specifiers go further and demand containers that include the exact quantity going in each cubic meter or cubic yard of concrete. If the specified dosage is 20 kg/m3 (33 lb/cy), each box or bag would have to contain exactly 20 kg (33 lb). This simplifies batching and reduces the risk of error. Some suppliers may have trouble packaging fibers in anything other than standard quantities.

Fibers should be stored under cover, protected from rain and snow. Left outdoors, boxes can disintegrate and fibers can rust.

Last, it is a good idea to insist all concrete tests, including those needed for approval of the mix design, be made after the addition of fibers. That may seem like common sense, but it will not always happen without a reminder.

Of course, it takes more than the right specification to make a successful steel-fiber-reinforced floor&#;it also takes a smart designer and a careful contractor. Nevertheless, a full, accurate specification is an essential part of the job when the floor is expected to fulfill the designer&#;s intentions.

George Garber is the author of Design and Construction of Concrete Floors, Concrete Flatwork, and Paving with Pervious Concrete. Based in Lexington, Kentucky, he consults on the design, construction, and repair of concrete floors. Garber can be reached by at .

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