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    Manufacturing Processes and Materials Exercises

    Uploaded by

    MedSpark
    3d Printing Grow-It

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    © All Rights Reserved
    Download as PDF, TXT or read online from Scribd

    Manufacturing Processes and Materials Exercises

    Uploaded by

    MedSpark
    30 views2 pages
    3d Printing Grow-It

    Copyright

    © © All Rights Reserved

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    PDF, TXT or read online from Scribd

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    3d Printing Grow-It

    Copyright:

    © All Rights Reserved
    Download as PDF, TXT or read online from Scribd
    Download as pdf or txt
    30 views2 pages

    Manufacturing Processes and Materials Exercises

    Uploaded by

    MedSpark
    3d Printing Grow-It

    Copyright:

    © All Rights Reserved
    Download as PDF, TXT or read online from Scribd
    Download as pdf or txt
    of 2

    ABS-M30

    ABS-M30 is up to 25-70 percent stronger than standard Stratasys ABS and is an


    ideal material for conceptual modeling, functional prototyping, manufacturing
    tools, and end-use-parts. ABS-M30 has greater tensile, impact, and flexural
    strength than standard ABS. Layer bonding is significantly stronger than that of
    standard ABS, for a more durable part. This results in more realistic functional
    tests and higher quality parts for end use. When combined with a Fortus 3D
    Production System, ABS-M30 gives you Real Parts™ that are stronger,
    smoother, and with better feature detail.

    Mechanical Properties1 Test Method English Metric


    Tensile Strength (Type 1, 0.125”, 0.2”/min) ASTM D638 5,200 psi 36 Mpa
    Tensile Modulus (Type 1, 0.125”, 0.2”/min) ASTM D638 350,000 psi 2413 Mpa
    Tensile Elongation (Type 1, 0.125”, 0.2”/min) ASTM D638 4% 4%
    Flexural Strength (Method 1, 0.05”/min) ASTM D790 8,800 psi 61 Mpa
    Flexural Modulus (Method 1, 0.05”/min) ASTM D790 336,000 psi 2317 Mpa
    IZOD Impact, notched (Method A, 23°C) ASTM D256 2.6 ft-lb/in 139 J/m
    IZOD Impact, un-notched (Method A, 23°C) ASTM D256 5.3 ft-lb/in 283 J/m

    +/- .005 1st in.; +/- .001 +/- .127 1st cm; +/- .025
    Typical achievable tolerance -
    every in. after every cm after

    Thermal Properties3 Test Method English Metric


    Heat Deflection (HDT) @ 66 psi, 0.125" unannealed ASTM D648 204°F 110°C
    Heat Deflection (HDT) @ 264 psi, 0.125" unannealed ASTM D648 180°F 96°C
    Vicat Softening Temp. (Rate B/50) ASTM D1525 210°F 112°C
    Coefficient of Thermal Expansion (flow) ASTM E831 4.9E -05 in/in/°F 8.82E-05 mm/mm/°C
    Coefficient of Thermal Expansion (xflow) ASTM E381 4.7E -05 in/in/°F 8.46E-05 mm/mm/°C
    Glass Transition Temp (Tg) DMA (SSYS) 226°F 108°C
    2
    Melt Point - Not Applicable Not Applicable2

    Other3 Test Method Value → See reverse for color


    Specific Gravity ASTM D792 1.04 options and system
    Flame Classification UL94 HB (0.06", 1.5mm) availability.
    Rockwell Hardness ASTM D785 110%
    Dielectric Strength IEC60112 28.0 kV/mm

    The information presented are typical values intended for reference and comparison purposes only. They should not be used for design specifi cations or quality control purposes. End-use material performance can be
    impacted (+/-) by, but not limited to, part design, end-use conditions, test conditions, etc. Actual values will vary with build conditions. Tested parts were built on Fortus 400mc @ 0.010” (0.254 mm) slice. Product specifi
    cations are subject to change without notice.

    1
    Build orientation is on side long edge. 2Due to amorphous nature, material does not display a melting point. 3Literature value unless otherwise noted.
    ABS-M30

    System Availability Layer Thickness Capacity Support Structure Available Colors


    Fortus 360mc 0.010 inch (0.254 mm) Soluble Supports Ivory
    Fortus 900mc 0.007 inch (0.178 mm) White
    0.005 inch (0.127 mm) Black
    Dark Grey
    Red
    Blue

    At the core: Get your benchmark on the


    Advanced FDM Technology Real Accuracy future of manufacturing

    Fused Deposition Modeling (FDM) is Because thermoplastics are environmentally Low Cost. Accurate. High Strength. The best
    the industry’s leading additive stable, part accuracy (or tolerance) doesn’t way to see the advantages of a FDM part is
    manufacturing technology. FDM change with ambient conditions or time. to have your own model built on one of our
    systems use a wide range (the largest This enables FDM parts to be among the many FDM systems. Get your parts at
    choice of options in the industry) of most dimensionally accurate. www.growit3d.com.
    thermoplastics with advanced
    mechanical properties so your parts can
    endure high heat, caustic chemicals,
    sterilization, and high impact
    applications.

    About GROWit
    GROWit™ is a privately held additive manufacturing company located in Irvine, California, dedicated to improving design through
    engineering and rapid prototyping. We strive to be at the cutting edge, bringing both knowledge and resources directly to customers.
    With our team of engineers, we help guide customers to the process that best suits their specific application, without holding a bias
    to a specific platform or technology.

    Why do we call ourselves GROWit? Due to the layer-by-layer nature of rapid prototyping, a part often looks like it is growing within
    the machine – just like a plant grows from the ground. Rather than using the terms “building” or “fabricating”, the term “growing” is
    commonly used within the industry; thus the origin of our name, GROWit.

    GROWit
    20918 Bake Parkway (p) 949 305 4004
    Suite 106 (f) 949 305 4915
    Lake Forest, CA www.growit3d.com
    92630 sales@growit3d.com

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