GPR X-Rays NDT testings for Concrete, Oil & Gas Installations & Aerospace sector are provided by us. We use radioisotopes or x-rays without radioactive materials or state of art pulse X-ray systems to provide digital imaging using X-rays, be it PT cables, steel rebar, Welds, interior flaws etc.
Our staff who perform x-ray service undergo special training and certification. Due to the service nature, our analysts are fully aware of different on-the-job hazards and the safety procedures to be followed. Regardless of the project scope, we always come prepared and ready to take on the challenge.
X-Rays GPR NDT testings are the non-destructive application of x-rays or gamma rays to image the interior of a concrete target to identify and locate rebar, conduit, post tension cables and other embedded objects. It is considered a branch of industrial NDT radiography testing. According to the EPA, radiography is useful when you want to avoid damaging the material being tested. Practically the most common targets for concrete x-ray are suspended slabs or concrete walls that may be renovated or retroﬁtted as part of a larger structure by cutting new openings.
Although cutting through rebar will weaken a structure it can often be achieved safely and within structural tolerance limits. Cutting through post tension cables poses more serious issues and is rarely deliberately executed. Likewise conduit should nearly always be avoided and accidental cuts can necessitate costly repairs, safety concerns and project slowdowns.
X-ray is often considered superior to GPR (ground penetrating radar) for imaging the interior contents of a concrete slab due to the clarity and accuracy the image. X-rays are also inherently easier to interpret. However, in practical field applications, GPR is a more common approach. X-ray imaging will always require access to both sides of the concrete target — so a slab on grade concrete target cannot use x-ray at all. Learn More about the difference between the 2 services.
An x-ray image is essentially a shadow or a projection of the density of objects that are targeted. As gamma rays strike a target, the photons will pass unimpeded through the softer less dense material, but will scatter or be absorbed by denser material. Steel will absorb more energy that concrete — leading to less x-rays hitting the detector directly in the straight-line from the emitting source to the detector. In effect a shadow is cast and recorded. As negatives are commonly examined rebar will show as a lighter patch (the in although with digital imaging it is very easy to reverse the contrast and show rebar and denser materials as darker. With ﬁlm a chemical reaction occurs when the x-rays meet the ﬁlm surface — and with DDA’s an electrical change is generated, which can be captured and quantified.
A typical concrete x-ray set up requires 2 operators — one for the detector and one for the source. While capturing the concrete imaging the 2 operators are on different floors — each making sure that the exclusion zone is clearly marked and no accidental intrusions occur. The detector is most often on the upper ﬂoor facing down while the x-ray source is below facing up, although an inverted setup is also possible. It is important to line up the detector with the source to ensure the emitted rays are directly striking the detector (perpendicular) and not coming from an angle. Complete remote control is possible, or the source operator will manually switch on the x-ray beam first (assuming a x-ray tube is used) and then call the detector operator to switch open the panel and take an image. When isotopes are used the source operator cranks out the isotope from its secure container exposing it the air and effectively firing gamma rays towards the detector.
Safety measures are vital and necessitate both operators to use a combination of survey meters and dosimeters to read the volume of radiation in their speciﬁc location and enforcing exclusion zones. Governing bodies set limits for exposure at a national and state level.
After an exposure the film is either developed in a dark room, or if a detector panel is used the image is captured immediately and displayed on a computer screen for enhancement and editing.
X-rays and Gamma Rays travel in straight lines through vacuums (for this purpose air behaves much like a vacuum). As they are generated from a source they spread out (like light from a bulb) and the intensity naturally decreases with distance from the source. The further away the source is from the target the weaker the signal (it follows an inverse square rule). For much of industrial radiography being close to the target poses no problems — particularly when the purpose is to ﬁnd the presence, or identity of an object rather than it's position or measurement. With concrete x-rays testings the customer is usually looking to make an alteration by a core or cut and requires x-ray imaging to avoid hitting an embedded object. In this case, it is actually better to place the x-ray source further from the target to ensure that the wave front hitting the target is as close as possible to being parallel to the target’s surface and the direction of X-ray travel is perpendicular. The advantage of this set up is that it minimizes dilation of the image from the center point — although some dilation is inevitable and cannot be avoided. The simple way to imagine this effect is to visualize your own shadow created by a point light source near to you, versus one created by rays originating from far away.
Concrete x-rays ndt testings are more expensive than GPR due to its accuracy. The equipment is more expensive and a minimum of 2 operators is needed at all times. As a rule of thumb, concrete x-ray will cost double the hourly rate of GPR — although pricing by image may be more attractive for both parties. $?5-$150 per image is fairly standard, combined with a mobilization charge of several hundred dollars. Night and weekend work is charged at 1.5 times standard rates which can lead to overtime rates too.
Protection from radiation is an important aspect of industrial radiography. The International Atomic Energy Authority (IAEA) had developed basic safety guidelines regarding the practice.