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Get accurate and high-quality inspection results with high-precision X-ray inspection machines.
With our variety of industry X-ray equipment, you are assured delivery of higher processing standards and reliable inspection at a reasonable cost and with lower emissions.
Our tried and tested solutions are guaranteed to simplify your testing challenges and integrate well with your existing processes.
We also ensure that our range of digital X-ray machines, like our high-resolution scanners, gives more precise results at a reduced cost and reduced environmental impact.
Due to our many years of providing digital X-ray solutions, we have developed advanced proprietary technologies. You can find these technologies in different industries, including automotive, aviation, art, oil and gas, and power generation.
They are applied for inspecting corrosion of metals, including turbine blades and the quality of welds. These applications are conducted faster with increased productivity and without the cost of frequent equipment repairs.
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The use of industrial radiography as a critical component of non-destructive tests is now more than just an engineering procedure.
Materials are inspected for defects by various methods for which industrial radiography is one. It has the advantage of seeing through hidden areas, which can be missed when using other inspection methods. To achieve this objective, Gamma rays and X-rays penetrate the atoms of different materials. This technology has been used in medical equipment and radiography cameras to achieve the same result previously.
In order to complete the process of material inspection, the two scanning methods used are industrial computed tomography or X-ray computed tomography. The sealed material inspected absorbs the X-rays released from the X-ray machine. An image is produced and analyzed for its internal workings.
The working of industrial radiography is dependent on the projection of gamma radiation or X-rays on the tested object with an aligned radiation detector. The work of the detector is to track the X-rays and Gamma rays that pass through the item.
The number of X-rays and Gamma rays that pass through thicker materials are fewer than for thinner materials. Where there are flaws in the material are lighter and will allow the passage of more X-rays and Gamma rays. The detector then produces an image for the X-rays that passed through the object’s flaws.
A radiograph is a name given to the image produced by the detector, which used to be film-based but has recently started becoming digital, just like photography.
Using industrial computed tomography and X-ray computed tomography are the options available for scanning objects for flaws. The sealed items receive the rays from an X-ray source, which provides the data to analyze the internal machinery.
Viewing objects with hidden parts can be difficult, and industrial radiography can help make it easy using ionization radiation. This type of radiation is often confused with the one that modifies an object, but it is different. The use of radiation is only for revealing hidden parts of things that are difficult to view.
This technology has become more than just an engineering tool. It is now a vital part of testing and inspection procedures, especially for non-destructive testing and inspection. It ensures that objects with hidden features get a thorough examination, and all flaws are revealed.
This process depends on the capacity of short X-rays and Gamma rays to pierce through materials to reveal their internal components. This approach is a common method employed in medical equipment and radiographic cameras.
Industrial radiography is also employed in our equipment, applied in the test of metal welding, vehicle parts, oil and gas pipelines, aircraft parts, and boilers.
Government requirements for the use of industrial radiography vary for different locations. They can include the use of some safety equipment as well as working as a pair. Also, specific areas will require radiographers to obtain some licenses and permits or complete special training in some cases.
An essential safety measure to take is the clearing of unauthorized personnel from the work area before the testing commencement. You should also take proper precautions to keep people out of the working space, so they cannot be exposed to large radiation doses during testing.
The three most important protective measures for radiographers involve shielding, time, and distance. Observing the right distances from the radiation source will often reduce large doses of radiation exposure.
Spending the minimum time with a radiation source will also keep the level of exposure and radiation dose low. A radiographer will also reduce the exposure level and radiation dose when the radiation source is adequately shielded from the operator.
Some typical materials used for their adequate shielding property include steel, tungsten, sand, water (when conditions are suitable), lead, and spent.
When using safety equipment in radiography, the items worthy of note include a rate meter or alarming dosimeter, a radiation survey meter, a film badge, and a gas-charged dosimeter or thermoluminescent dosimeter (TLD). These four items are essential safety tools and can be compared to the gauges in an automobile.
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