Additive Manufacturing Materials and Component Testing Services
IMR's Additive Manufacturing testing lab has expanded capabilities in powdered metal characterization, and laser-sintered metal testing & analysis to help manufacturers quickly and accurately make important evaluations for their products design, development and production phases.
For example, IMR provides comprehensive powder analysis to fully characterize the starting powder via test methods such as chemical analysis (ICP-AES, ICP-MS), percent crystallinity testing, particle size testing (Microtrac) and morphology analysis (XRD, SEM and optical). Additionally, we offer density testing to determine how compact the sample has become after bonding, and compression testing to determine how much force a sample can handle. A full list of analytical services offered by IMR for Additive Manufacturing is listed below. Or if you're ready for a quote, click the button below.
Many additive manufacturing (AM) challenges are being overcome through the use of materials testing and analysis. This starts with the need for well characterized raw materials such as powders, pastes, and wires. SLS powders especially needs ongoing testing due to the need to reuse unsintered powder without affecting the end product.
Additive manufactured component quality requires the analysis of a wide array of properties, based not only on the end use of the part, but also the AM process being used to produce them. With the push towards lighter, more durable products created with AM technology, supply chains need to insure that their products meet or exceed physical characteristic specifications.
Additive manufacturing video
IMR Test Labs has extensive experience in providing world-class materials testing and analyses. This video highlights the main (and specialized) areas of materials testing involved in materials characterization of additive manufacturing powders, wires and finished products.
MATERIALS CHARACTERIZATION TESTING Lab Methods
This measurement is in a direct inverse relationship with porosity. A reduction in density due to porosity can lead to fatigue and cracking when pressure is applied. An evaluation of Particle Size Distribution is helpful, since a proportional number of small particles can fill in the gaps around the larger particles, reducing porosity and increasing density.
During the metal 3D printing process, residual stress is created due to the inherent heating/cooling cycles, as well as expansion/contraction. Cracking can occur when the residual stress exceeds the printing material’s tensile strength. The most vulnerable location for this issue is the common interface between the part being manufactured and the build plate.
When melted metal solidifies, the risk of cracking increases. Careful monitoring of the energy source to keep its output level consistent and moderate during production/printing will help mitigate the potential for damage. The quality and characteristics of the alloy powder are critical in maintaining the integrity of the printed part. Delaminating can also occur when powder is not melted to an adequate level, or escapes to form a re-melting layer under the melt pool.
In addition to providing incredible flexibility in design, additive manufactured products need to meet strength and durability standards. Mechanical testing offers a variety of methods.
ANALYTICAL SERVICES FOR ADDITIVE MANUFACTURING TESTING
C, H, O, N, S
DSC Analysis (Melting Point, Glass Transition, % Crystallinity, Degree of Cure, Purity)
Filler Content Analysis
Halogen Analysis (IC)
Heavy Metal Impurities
ICP-MS Trace Element Analysis
Ion Chromatography (IC)
Positive Material ID (On-site PMI available)
Precious Metal Assay
Trace Element Analysis
Unknown Material ID
X-Ray Diffraction (XRD)
Certified Weld InspectionsDecarburization
Microhardness (Knoop, Vickers, MacroVickers)
Orientation in Microstructure
Particle Analysis (Distribution, ID, Size)
Phase Volume Determination
Quantitative Image Analysis
Root Cause Evaluation
Bond Strength Testing
Charpy Impact Testing (-320°F to 450°F)
Coefficient of Thermal Expansion by TMA
Composite Testing (FRC, CMC)
Creep & Stress Rupture
Fatigue Testing (Axial, Low Cycle, High Cycle, Rotating Beam, Coating Shear)
Flexural Properties (Modulus, Strength, Stress-Strain Response)
Hardness (Rockwell, Brinell)
Impact Testing (Charpy, IZOD)
Lap Shear Testing
Open Hole Tension/Compression
Slow Strain Rate
Taber Abrasion/Wear Resistance
Tensile Testing - Metals (to 2000°F)
Torsional/Axial Fatigue (200 lb)
DOWNLOAD OUR FREE EBOOK- MATERIALS TESTING FOR THE ADDITIVE MANUFACTURING INDUSTRY
TESTING AND ANALYSIS OF RAW MATERIALS AND FINISHED PRODUCTS IDENTIFIES POTENTIAL ISSUES IN PRODUCTION AND FINAL APPLICATION OF PARTS
While Additive Manufacturing is a huge growth industry, new technologies are making the choice for raw materials a more complex decision. Taking into account design geometries, operating environments and budget concerns, AM companies have a strong need for accurate materials characterizations to enable them to project a part's design viability and operating durability.
Find out how IMR Test Labs uses a multi-disciplinary approach to Additive Manufacturing testing and analysis. Click here (or on the button below) to download our eBook.