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Importance of locating steel reinforcement in concrete

Accurate location and identification of embedded concrete reinforcing steel is a primary step in nondestructive evaluations of reinforced concrete structures or pavements. Likewise, if core drilling is required for the installation of utilities or to obtain concrete strength samples establishing bar locations avoids damage to the integrity of the reinforcing steel.

How to find reinforcement in concrete

Cover meters and rebar locators, sometimes called pachometers, are versatile devices indispensable for any organization involved in the design, construction, or testing of concrete in structures or pavements. They permit the user to quickly and economically make a structural condition assessment of reinforcing steel installations without disturbing concrete. If coring is required, they guide the location of the hole to avoid damage to rebar, post-tensioning tendons, and some embedded utilities.

Concrete cover meters and rebar locators have been used for decades for these purposes and have steadily kept pace with advances in electronics and instrument design. These devices are offered with many different levels of functionality and features to meet the needs and preferences of the user. This blog post will help you understand the equipment and what your options are for selecting the best meter for your application.

Cover Meter and Rebar Locator Applications

Primary uses for these devices center around nondestructive initial investigations, as well as preventing potential damage to reinforcing steel by identifying areas where it exists before cutting or drilling. Some examples:

• Nondestructive evaluation of the reinforcement matrix:
  • Measuring the depth of concrete cover for structural compliance, corrosion resistance, and fire protection
  • Ensure correct bar placement and spacing
  • Measuring bar diameters to ensure compliance with design requirements
  • Locate wall ties, splices, tendons, and other metal embedments
  • Proper splice lengths
• Avoiding damage to reinforcing steel during penetrations by saw cutting or core drilling operations. Accidental damage to reinforcing steel can seriously compromise the integrity of a structure.

Functionality and Features

Just as there are different reasons for defining the location and characteristics of concrete reinforcing steel, there are different types of rebar locators and cover meters. The classes of instruments are not strictly limited, but there are general groupings based on function and design:

• Cover Meters perform a complete nondestructive evaluation of concrete reinforcing steel. They accurately measure the location, diameter, and embedded depth of steel reinforcing bars. A quality concrete cover meter is the best tool for assessing the integrity of the entire reinforcing steel system. Multiple pulse induction coils generate eddy current magnetic fields, inducing an opposite magnetic field on the surface of electrically conductive materials in the eddy current field. The resulting change in voltage creates a signal that can be processed to determine the location of rebar, depth of concrete cover, and rebar diameter. This method is unaffected by nonconductive materials such as concrete, wood, plastics, bricks. The measurements are also not influenced by&#;moisture, non-metallic inclusions, or voids in the concrete. Conductive materials within the magnetic field will influence measurements.
• Rebar Locators use similar detection technology, but the apparatus is more economical, compact, and simpler to operate. Electronic signal processing is not as sophisticated, so while location accuracy and tolerance are comparable, estimations of concrete cover depth, bar diameter, and wide-area evaluations are less precise. Choose a rebar locator for frequent applications like utility penetrations or coring for concrete strength samples among closely-spaced individual bars. They can also accurately locate the exact position of embedded wall ties, wire mesh, studs, and other metal fasteners.
• Metal Detectors are effective in less demanding applications where the general locating of widely-spaced bars is sufficient. Many detectors can differentiate between ferrous and non-ferrous metals and reduce confusion in the presence of metals (i.e., copper pipes) that are not part of the reinforcement system. The lower resolution makes it harder to define exact locations and boundaries, and the detection circuitry can be subject to interference.
• Ground-Penetrating Radar (GPR) Concrete Scanner is the &#;New Kid on the Block&#; has been around for some time in applications that explore subsurface soil conditions, archaeological remains, or underground utility locations. Recent advancements in frequency tuning and sensor technology have opened up the field for the nondestructive evaluation of hardened concrete. Modern concrete GPR instruments accurately locate and size large reinforcing bars as much as 2ft (610mm) below the surface. Beyond that, they form a complete representation of voids, inclusions, delamination, and utilities beneath concrete surfaces. Some models use advanced signal processing to render three-dimensional subsurface views for a clear presentation of data. It should be noted that conductive materials, other than reinforcing steel bars, located within the magnetic field will affect the accuracy of meter readings.

Instrument Capabilities and Performance

Measuring capabilities claimed by different manufacturers of detectors, locators, and cover meters vary widely, and it can be challenging to pin down a meaningful comparison between models. Some units claim detection at extended depths and accuracy levels, but the results may only be meaningful for large bars spaced widely apart, or at a significant reduction in accuracy tolerances. It is well worth the time for a careful review of performance specifications before making a purchase decision. The job at hand may not always require a very high degree of accuracy, but you should understand the limitations of the equipment you choose.

In ideal conditions, a high-quality eddy current cover meter accurately measures concrete cover up to 185 ±4mm (7.3 ±0.16in), and bar diameters to a tolerance of ±1 rebar size to a depth of 63mm (2.5in). So, in general, 12 or 16mm (#4 or #5) reinforcing bars can be individually located and reliably measured for cover at depths around 125 to 140mm (5 to 5.5in) and diameter to about 63mm (2.5in). Measurements may still be possible beyond these limits at reduced accuracy. Less expensive metal detectors locate various metal objects up to 152 ±25mm (6 ±1in) depths with a positional accuracy of 13mm (0.5in) and are not reliable for accurate determinations of bar size.

Modern cover meters and locators feature a wide array of technological innovations that improve accuracy, recording, reporting, and ease of use while meeting BS , Part 204, and other standards. Advances in electronics allow improved accuracy, especially in installations where rebars have very close spacing. Touch-screen color displays simplify operation and display complete measurement information, including visual mapping of concrete cover with the depiction of rebar locations. Electronic data systems collect test values and locations, perform statistical analyses, and prepare reports for upload to computers and printers.

Technology advances of the probes alone have kept pace with those of the complete instruments. Specialized test probes are available to scan large areas, pinpoint individual bars in congested installations or corners or find rebars at extended depths. The probes can be mounted in small, wheeled carts for smooth, fast operation on walls or used with extension handles to scan large areas of floor slabs or ceilings with no need to bend over or climb a ladder.

Gilson's Recommendations:

Profometer 6 Cover Meters
Are flexible with scalable features and optional software activation codes for instant upgrades of basic models. Color touch screens allow extensive function control and graphic displays. Available kits with additional probes convert from rebar location and measurement units to meters that measure reinforcing steel corrosion using the ASTM C876 half-cell method.

Are flexible with scalable features and optional software activation codes for instant upgrades of basic models. Color touch screens allow extensive function control and graphic displays. Available kits with additional probes convert from rebar location and measurement units to meters that measure reinforcing steel corrosion using the ASTM C876 half-cell method.

Profoscope Rebar Locators/Cover Meters
Are easy to operate with one hand for instantaneous and straightforward locating of steel rebars. The device is equipped with audio and visual directional alerts and can find the midpoint between bars. It has the capabilities of locating reinforcing steel up to 7in (180mm) maximum depth.

Are easy to operate with one hand for instantaneous and straightforward locating of steel rebars. The device is equipped with audio and visual directional alerts and can find the midpoint between bars. It has the capabilities of locating reinforcing steel up to 7in (180mm) maximum depth.

Elcometer Cover Meters
Are accurate and reliable, and designed for locating the depth and placement of rebar. The 331 series has accuracy levels that exceed requirements. A backlit screen displays numeric values. Optional narrow pitch and deep-cover search heads are available, and selected models are convertible to half-cell corrosion meters.

Are accurate and reliable, and designed for locating the depth and placement of rebar. The 331 series has accuracy levels that exceed requirements. A backlit screen displays numeric values. Optional narrow pitch and deep-cover search heads are available, and selected models are convertible to half-cell corrosion meters.

Handheld Digital Metal Detector
Is inexpensive and effective for the general locating of widely spaced reinforcing steel. It is best used for preliminary scanning to detect the location and approximate depth of rebar, metal pipe, conduit, and most non-metallic construction materials. They can be a convenient everyday component of your field inspection kit.

Is inexpensive and effective for the general locating of widely spaced reinforcing steel. It is best used for preliminary scanning to detect the location and approximate depth of rebar, metal pipe, conduit, and most non-metallic construction materials. They can be a convenient everyday component of your field inspection kit.

Ground Penetrating Radar (GPR) Concrete Scanner
Is a handheld ground-penetrating radar unit. Allows for a quick and reliable assessment using Stepped Frequency Continuous Wave (SFCW) technology The Proceq GP GPR Live is available in 3 model options each with different levels of features, functionality, and data storage.

Is a handheld ground-penetrating radar unit. Allows for a quick and reliable assessment using Stepped Frequency Continuous Wave (SFCW) technology The Proceq GP GPR Live is available in 3 model options each with different levels of features, functionality, and data storage.

For additional assistance or to discuss other nondestructive testing equipment for concrete that is best suited for your needs, contact a member of our technical support team today!

Rebar Size Guide & Charts: Grades, Types, and Weight Specifications

While it's not visible in the final product, rebar plays a part in the majority of concrete projects. Rebar provides reinforced strength to any concrete structure to help them resist forces like stretching, bending, or twisting. All of these forces happen to buildings as a result of environmental factors over time. Using these reinforcing steel bars allows the structure to handle heavier loads and resist deflection.

Increasing the lifespan of structures is the main motivator for using rebar. The way that concrete and rebar work together to reinforce the concrete is crucial to the building's structural integrity and longevity. Rebar comes in a variety of different grades that are represented by the minimum yield strength of the steel. These different types of rebar are used across several building types.

How to Read Rebar Markings

At the very top of the piece of rebar, below the main ribs, there will be a letter or a symbol to indicate the production mill. Below that, there will be a number that will indicate the bar size.

Underneath the bar size, there will be a letter, usually S (carbon steel), A (axle steel), W (low-alloy steel), SS (stainless steel), or CS (low-carbon chromium). These letters resemble the type of reinforced steel.

The last marking you will find is the grade mark. The grading scale is represented by a set number of lines to represent the grading. A rebar size of 60 is represented by one line, 75 by two lines, 80 and 100 by three lines, and 120 by four.

How to Measure Rebar Diameter

To determine your rebar's diameter, you should measure the thickness of the rebar across its circular cross-section. This can either be done by using a caliper or tape measure.

When using a caliper, open the jaws and place the rebar perpendicular to the rebar's axis. From there, slide the caliper's jaws together until they touch on opposite sides of the circular rebar. Then record the measurements shown on the caliper's scale.

When trying to measure larger-diameter rebar, it's recommended that you use a tape measure. Wrapping the tape measure around the rebar, ensuring it forms a circle around the thickest part of the rebar. Note the measurement where the tape measure overlaps.

For example, if you measure 12 millimeters using a caliper or find that it aligns with the 1/2" mark on a tape measure, the rebar is 12 mm or 1/2" in diameter, respectively.

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Rebar Size Chart

Below is a rebar size guide that can help you decide what is the most appropriate rebar for your construction needs.

Rebar Size Chart

Imperial Bar Size

Weight per unit length (lb/ft)

Mass per unit length (kg/m)

Nominal Diameter (in)

Nominal Diameter (mm)

Nominal Area (in^2)

Nominal Area (mm^2)

#3

0.....

#4

0....70.

#5

1.....

#6

1..240..050.

#7

2.....

#8

2.673...40.

#9

3.45...

#10

4....261.

#11

5....811.

#14

7..411..

#18

13.620...

What are the Rebar Grades?

Learning about rebar grades is necessary and it's also crucial to understand what is being measured. This includes both tensile strength and yield strength. Tensile strength refers to the maximum stress that a material can withstand before it breaks when stretched or pulled. It is measured in pounds per square inch (psi) or megapascals (MPa). Yield strength is the stress at which a material begins to deform, and it is also measured in units of force per unit area, such as psi or MPa.

Rebar comes in multiple grades, with specific grades depending on the standards within that region. The most five common grades are 40, 60, 75, 80, and 100.

Grade 40 rebar has a minimal yield strength of 40,000 pounds. Grade 60 rebar has a minimum yield strength of 60,000 psi or approximately 420 MPa. It is one of the most commonly used rebar grades for general construction purposes.

Grade 75 has a minimum yield strength of 75,000 psi or around 520 MPa, making it optimal for high-stress applications and structures that need higher strength. When a project demands a grade greater than 60 or 75, rebar with a grade of 80 is used. It has around 550 MPa and 80,000 psi as a minimum yield strength.

Grade 10 is the most high-strength rebar with a minimum yield strength of 100,000 psi or around 690 MPa. Overall, the appropriate rebar grade for the project is based on the structural design requirements, load-bearing capacity, and environment.

Types of Rebar

Some rebar types are better suited for specific environments. Mild or black rebar is most frequently used for the majority of general construction purposes. This type of rebar is used because of its strength and durability. Additionally, most general construction projects are not exposing the rebar to high-humidity locations.

Epoxy-coated rebar is most commonly used in corrosive and marine environments. Having an epoxy coating on the rebar helps to provide extra protection against corrosive elements and moisture. Stainless steel rebar is most frequently used in situations where corrosion resistance is the primary concern. Stainless steel rebar provides strength and long-term resistance from chemicals, like road salt and other chemicals.

Rebar comes in various grades, with different yield strengths, and it's available in different types suited for specific building requirements. Using rebar significantly extends the lifespan of structures as it works side by side with concrete to enhance structural integrity, ensuring durability and longevity.

Providing tensile strength, rebar enables structures to resist the stretching, bending, and twisting caused by environmental factors. This reinforcement allows buildings to handle heavier loads and resist deterioration. Understanding the importance of rebar will help you construct more formidable, cost-effective projects.

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