Why use a CT scanner for an industrial job?

Published
June 26, 2019 - 02:15pm

The ability to “see through” a solid object was once thought to be a tool of the future, or a power belonging to Superman–but the technology is here today, and more widespread and accessible than you may have thought. Until recently, the technology of CT imaging was only available for use in medical settings. Over the last several years, it has found a new home in the world of manufacturing, and is opening up myriad opportunities never before available.

CT, or computed tomography, is now commonly used in various industrial metrology settings, both in the lab and online or inline for product evaluation and packaging integrity assessment. The main advantage is that it allows the inspection of a part’s interior structure or a package’s closure functionality without causing any harm or destruction to the objects themselves.

CT scanning machines need significant shielding to protect operators from X-ray exposure. Photo credit: Exact Metrology

CT scanning machines need significant shielding to protect operators from X-ray exposure. Courtesy of Exact Metrology.

Industrial CT scanners utilize the same type of technology as CT scanners in hospitals and doctors’ offices, taking multiple readings from various angles and converting the CT gray scale images into voxel-based 3D point clouds. Once the CT scanner generates the point cloud, a specialist can generate a CAD-to-part comparison map, construct a 3D model of the part, or reverse engineer the part to suit their needs. In the packaging world, especially where pharmaceutical or personal products are concerned, this ability is paramount. High-speed scanning inline, for example, can examine the seals on pill bottles for airtight quality assurance, while online or lab scanning can instantly compare a manufactured product to the CAD program in various ways.  

Industrial scanners offer a multitude of advantages, such as obtaining internal structure of an object nondestructively, validating extremely accurate internal dimensions, allowing comparison to reference models, no shaded zones, compatibility with all shapes and sizes, no post-processing work and extremely high-resolution imaging.  

Some of the most common uses of 3D and now CT scanning in industrial metrology applications include:

  • Reverse engineering – the process of taking measurements of an existing part or object, then creating an exact CAD replica. This technology is extremely useful, when you have a manufactured part or object, but not the original prints or design data.
  • Non-contact measurement – the process of capturing the geometry of existing objects through the use of laser emitting camera-like 3D scanners.
  • Contact measurement – a method of collecting single points relative to each other. There is a wide range of solutions for contact measurement and generally two types of systems solutions are used with portable CMMs: 1) For capturing localized or small volume information, digitizing or articulating arms are used, 2) For larger volumetric projects, optical solutions including laser trackers and photogrammetry units.
  • Long-range scanning – for a detailed 360° 3D snapshot of a structure, bridge, plot of land, plant or process operation with millimeter accuracy.
  • Art forgeries – a bit unusual for what is thought to be an industrial product, but hundreds of art museums, dealers and auction houses use scanning each year to validate works of art, as well as the structural integrity of sculpture, for example.
  • Model to manufacture processing – here again, artists will often have their models, whether fashioned or human, scanned for dimension prior to casting a statue in bronze or producing a high-fashion line of clothing.

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These 3D imaging devices and long-range scanners serve a wide range of industries, and help assure that they are performing the highest level of testing and accuracy possible. A few of the diverse industries currently using this technology and the goals sought are:

  • Manufacturing – for internal inspection of components and to ensure that a part meets specifications; this includes injection molded, cast, forged or fabricated parts made from metal, plastic, polymers, composites and even 3D printed products
  • Power generation/nuclear – can scan the complex, hard to reach and hazardous areas of a nuclear power plant or conventional power generation facility for pipe alignment, boiler integrity, containment building stability and more
  • Medical – devices and equipment, implants, orthotics and prosthetics; a one-off knee joint, for example, can be accurately compared to the original CAD program as well as the doctor’s MRI for accuracy
  • Automotive and aerospace – allows engineers to do virtual testing of machinery, helps understand failures, works as an R&D tool to analyze structure, simulate reactions
  • Arts – in the detection of forgeries and sculpture integrity
  • Metal castings – to check for air bubbles and overall porosity
  • Foods – to examine contents and packaging integrity
  • Plastics industry – to inspect quality, wall-thickness and porosity analysis
  • Moldmaking - provides a powerful inspection and measurement tool to validate precise injection molds and check structural integrity of a part

There is a wide range of industrial scanning equipment styles and sizes available to suit different types of applications. Microscale units in tabletop styles for lab use up to full industrial grade floor models for in-plant or in-process use, to portable measuring arms that can be used on the shop floor or out in the field are all available today, usually from a manufacturer or a service organization, for one-time contract use, with rent or lease-to-buy arrangements optional.  

Many of our customers, having used our services, subsequently purchase the equipment and training to add this high-end metrology to augment their inside CMM or test lab, for example. In the case of larger production facilities, we often see metrology today being integrated into the line for instant analysis of parts, whether molded, stamped, welded or otherwise fabricated, as well as packaged goods.  

Typical CT scanners offer a wide range of measurement capabilities and features. Sizes start with small desktop models, which meet the most stringent demands and measure the smallest 3D detail from 0.25µm. They can be equipped with different X-ray powers, from 160kV for nanometer resolution through 225kV, 320 Watts to the highest power of 300kV, 320 Watts.

Larger scanners are available for extremely fast CT data acquisition on workpieces up to 500 mm in diameter and 600 mm in height, weighing up to 50 kg (110 lbs.). Typical functions performed on this type of system might include 3D analysis of a scanned turbine blade, automatic pour porosity volume analysis on an aluminum casting and 3D measurements with nominal-actual CAD comparisons on a machined aluminum cylinder head.

The future of industrial scanning holds unlimited possibilities, especially when combined with 3D printing or other additive manufacturing methods. As improvements are made in technology and performance and costs continue to decrease, the industrial scanning industry is preparing for explosive growth in the next five to 10 years.

Related Glossary Terms

  • composites

    composites

    Materials composed of different elements, with one element normally embedded in another, held together by a compatible binder.

  • computer-aided design ( CAD)

    computer-aided design ( CAD)

    Product-design functions performed with the help of computers and special software.

  • land

    land

    Part of the tool body that remains after the flutes are cut.

  • metrology

    metrology

    Science of measurement; the principles on which precision machining, quality control and inspection are based. See precision machining, measurement.

  • quality assurance ( quality control)

    quality assurance ( quality control)

    Terms denoting a formal program for monitoring product quality. The denotations are the same, but QC typically connotes a more traditional postmachining inspection system, while QA implies a more comprehensive approach, with emphasis on “total quality,” broad quality principles, statistical process control and other statistical methods.

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