This site uses cookies to store information on your computer. Learn more x

Additive Manufacturing

Somos® Momentum

Last updated on 18 July 2019

Somos® Momentum provides a compelling solution that combines rich feature detail and dimensional stability with the most efficient printing outcomes available without compromising on surface quality and dimensional accuracy.

Rich feature detail and dimensional stability

somos-momentum-2

Stereolithography has enabled a faster route to market for footwear, while reducing development cost and aiding development of more complex shoe designs. With Somos® Momentum, DSM provides a compelling solution that combines rich feature detail and dimensional stability with the most efficient printing outcomes available without compromising on surface quality and dimensional accuracy.
 

Download the technical data sheet here.

Technical Data

Optical Properties

Ec 13.0 mJ/cm² [critical exposure]
Dp 6.25 mils [slope of cure-depth vs. In (E) curve]

Safety Instructions

Avoid injuring yourself or others

Please adhere to the following guidelines:

  • Read and understand the Safety Data Sheet (SDS) before using the material.
  • Avoid contact with eyes, skin & clothing by wearing the following Personal Protective Equipment (PPE):
    • Safety Glasses/Goggles
    • Gloves
    • Laboratory Coat
  • Keep the work area clean.
  • Avoid spreading material on clean surfaces.
  • If material is found on clean areas, it should be cleaned off immediately with a disposable paper towel and isopropanol.
  • Wash hands regularly after handling material.
  • Provide adequate ventilation.
  • Prevent build-up of volatile substances from materials and solvents.
  • Remove dust from clean and finished parts.
  • See the DSM Safe Handling Guide for UV materials for further safety instructions.

Preparing Equipment

Operating conditions

We recommend the following room conditions:

  • Ambient temperature of 20oC – 25oC (68oF – 77oF)
  • Humidity of less than 40%.
  • Minimize dust, as it can build-up and reduce the performance of the optics on your SLA machine, potentially leading to an increase in scattered UV light. Ultimately, this could increase the viscosity of the material in the vat.
  • Use UV filters for lighting and external windows.

Replacing Material

When replacing material, make sure you clean the vat thoroughly, dispose of used material and cleaning products (solvents, paper towels, etc.) properly and follow vat installation procedures.

Machine Maintenance

Contact your equipment supplier for up-to-date technical support for your equipment. Below are a few common checks that will help you build parts successfully:

Recoater Blade

  • Keep the re-coater blade clean. Remove debris from the bottom and periodically check the gap and rake of the blade.
  • Periodically check the rim level.
  • Keep bearing rails clean and oiled.
  • Periodically check belts, sprockets and bearings.

Optics and Overhead Mirror

  • Keep mirrors and optics dust free and clean. Periodic preventative maintenance will increase the life of the laser beam and improve its quality.
  • Have the laser tuned and serviced periodically. The typical tuning frequency is two to three times a year. This reduces the risk of burn spots on the laser crystals.

Machine Computer

  • Inspect the cooling fans for electronic components regularly to ensure they are working properly.
  • Keep the build tree clean. Having too many build files can corrupt the procycon.mdb, which contains material data, start position and sensor locations.
  • Install back up hard drives to ensure you do not lose any data. This is very important, especially for older equipment.
  • Make sure the latest computer software service packs are installed are your system for optimal performance.

Build Parameters

Build parameters are subject to site conditions and machine efficiency. The parameters mentioned below can be considered base settings that you can tweak for improved styles.

Machine Settings

Check to see that the Zephyr blade is clean of any residue by running a gloved finger along each side of the blade. If there is any residue, gently wipe it off with the proper tool.

Before beginning a new build, always check the Zephyr blade to ensure there were no changes after any build crash or other adverse events that may have changed the gap.

Also, check that the resin level in the blade is set to the halfway point. On builds with large flat or trapped volumes, check that the blade does not run out of material. If it does, material starvation could be causing it to give an incomplete part re-coating.

Build Styles

The build style of choice is Exact™ (Old Aces™). It offers the best:

  • Mechanical and physical properties
  • Closest dimensional tolerances
  • Clarity of substance.

Solid State Laser Calculation 

To achieve an even thickness using a solid-state laser with Exact™, perform the following calculation: Smax = 0.4* DL * FL *1000

  • Smax = Maximum recommended scan speed
  • 0.4 = Factor required for 60% overlap of laser pulses (to produce even thickness)
  • DL = Laser beam diameter in the imaging field (inches)
  • FL = Laser beam repetition rate (Khz)
  • 1000 = Conversion from Khz to Hz

Beam Diameter

The minimum beam diameter (in X or Y directions) should be used when calculating the maximum scan speed.

Smax Calibration

To ensure that the Smax is properly calibrated, please refer to the following chart of common stereolithography machines. 

The Smax should not exceed the recommended hatch speed for the machine being used.

Machine Nominal Spot
diameter (inch)
Nominal Spot
Diameter (mm)
Repetition
Rate (Khz)
Smax
Viper 0.010 0.254 30 120
Viper 0.003 0.085 30 36
250ss 0.010 0.254 60* 240
3500 0.010 0.254 22.2 89
500ss 0.010 0.254 60* 240
5000 0.010 0.254 40 160
7000 0.030 0.762 35 420
7000 0.010 0.254 35 140

Postprocessing

Part-cleaning Procedure

  • Drain excess material off the parts in the vat.
  • Remove the platform from the machine and remove the parts.
  • Wash the parts for 20 minutes in an automated parts washer, such as Ramco, or an ultrasonic cleaner. Please contact your machine’s manufacturer for use of recommended solvents.
    • If needed, place the parts in an ultrasonic cleaner filled with non-volatile solvents, such as TPM or Propylene Carbonate, for 20 minutes. If excess material is still present after 20 minutes, repeat another 20 minutes in the ultrasonic cleaner.
  • Drain parts, then rinse them with 99% isopropanol (IPA). Brush the parts with isopropanol. This removes the solvent, as well as any remaining excess material.
  • Dry the parts with compressed air and place them in a well-ventilated area to allow all absorbed solvent to vacate the part.

Manual and Ultrasonic Cleaning

During a build, you may find that excess material builds up on flat surfaces and in cavities. There are two ways to clean these:

  • If the surface is flat, simply scrape it with a spatula to remove any excess material. You can return the excess material to the vat prior to re-mixing.
  • Cavities and tight angles that act as trap volumes can be cleaned using an ultrasonic cleaner. The excess resin can then be returned to the vat prior to re-mixing.

Post Cure Procedures

UV Post-cure

After thoroughly air-drying the parts and checking that they are free from liquid resin residue, UV post-cure the parts for 20 minutes, rotating the part once after 10 minutes.

Disposal Instructions

Avoid injuring yourself or others

In some areas, partially cured or uncured waste UV material may be classified as hazardous waste, and requires special packaging.

Transportation disposal

Contact the governmental or other body that regulates waste disposal in your area to determine the disposal protocols.

Packaging-Transportation-Disposal Methods

Packaging-Transportation-Disposal methods must prevent any form of human contact with the waste UV material, even if it is classified as nonhazardous or unregulated. This therefore precludes the use of disposal methods that might result in groundwater or surface water contamination.

Solvent Disposal

Solvents should be isolated in a sealed, marked container and disposed of as “hazardous waste” in accordance with all applicable laws and regulations.

Clean-Up Material Disposal

Soiled clothing, empty containers, etc., should be disposed of in accordance with the applicable “hazardous waste” guidelines. If any of these items contain uncured or partially cured UV-curable materials, the disposal method used must prevent any form of human contact, including any that could result in groundwater or surface water contamination.

FAQ/Troubleshooting

Below are some examples of common issues and troubleshooting solutions. Consult this part of the guide if you are having difficulties and do not hesitate to contact our Tech Support.

Issue: Delamination

Delamination occurs on the bottom layer of parts at the corners or on part edges.

Solution: Check Blade

Have the physical gap on your re-coating blade checked.

  • For Zephyr blades
    • Set the blade gap to 0.004 inches (0.102 mm)
  • For doctor blades
    • Set the blade gap to 0.006 inches (0.1524 mm).

Watch the buildup of the first few layers of the part to determine that the surface is being properly coated with material. Check for signs of material starvation or de-wetting.

Issue: Roughness

The top surface of the part is not smooth and level.

Solution: Check Re-coating Blade 

This condition is somewhat common and arises due to the viscosity of the material and the presence of debris that may become suspended in it.

Check the re-coating blade to make sure the bottom surface is clean and filter debris from the vat.

It is very important that you maintain the correct material viscosity in your stereolithography machine. The viscosity can increase over time, and this can cause problems in building parts. If the viscosity increase is severe enough, the material may have to be replaced, resulting in significant expense and lost production time.

If increasing viscosity is identified early, the material can, in most cases, be saved. Regularly measuring resin viscosity can provide an early indication of the problem. This must be done even if the machine is not used often, as resin viscosity can change even when the machine is idle.

Viscosity Measurement

Depending on the viscosity range of the material you want to test, use the appropriate-sized cup, based on Zahn Cups guidelines. You will also need a long-stem thermometer that mounts onto the Zahn cup handle and a stop watch.

Procedure:

  • Ensure the material in the vat is at part-building temperature.
  • Mount the thermometer on the Zahn cup handle and hold the tip of the thermometer so it is half way up the bowl. The tip of the thermometer should not touch the material in the bowl, but be suspended above it.
  • Turn the thermometer on and set it to Celsius.
  • Lower the machine platform about 100 mm below the material surface.
  • Slowly immerse the Zahn cup at a 45° angle into the vat of material, being careful not to create bubbles, and rest the cup on the platform. Be careful that it does not fall into the material.
  • Monitor the temperature of the material with the thermometer. Wait until the Zahn cup and material have reached the vat temperature. Once the Zahn cup thermometer shows a steady reading, you can take a measurement.
  • Slowly lift the Zahn cup completely out of the material. Start the stopwatch when the top of the cup leaves the material.
  • Watch the stream of material flowing from the hole at the bottom of the cup. When the stream just under the cup breaks and changes from a continuous flow to individual drops, stop the stopwatch.
  • Read the number of seconds on the stopwatch and use the table on the following page to determine the approximate viscosity of the material.
  • Repeat the procedure to obtain at least two values that are close to each other. When finished, turn the thermometer off to save the battery.
  • Record the following data in a chart for each material and machine:
    1. Date
    2. Temperature of material
    3. Readings (seconds)
    4. Viscosity (from table)
  • If the viscosity of the material starts to increase significantly after having been stable for some time, inform Somos® and provide us with the data from the table.
  • Clean the cup and thermometer by wiping them with a paper towel. Wash the cup and thermometer stem with solvent and dry them. Do not remove the long-stem thermometer from the Zahn cup until the stem is completely clean.

Remember: Whenever you have material in your machine, measure and record its viscosity once a week.

Table of approximate viscosity in cps linked to Zahn #4 cup test time

 

Seconds Approximate Viscosity (CPS)
20 245
22 280
24 310
26 340
28 375
30 410
32 440
34 470
36 505
38 540
40 570
42 600
44 635
46 667
48 700
50 730
52 765
54 800
56 830
58 860
60 895
62 930
64 960
66 990
68 1030
70 1060
72 1090
74 1120
76 1150
78 1190
80 1220
82 1255

Contact

For a fast reply to any questions you have about the proper use and optimization of Somos® products, contact our Tech Support.

Ordering and Customer Service

Americas

1122 St. Charles Street
Elgin, Illinois 60120
USA
Tel. 800-222-7189 (U.S. and Canada)
Tel. +1-847-468-7809 (other countries)

Europe

Slachthuisweg 30
3151 XN Hoek van Holland
The Netherlands
Tel. +31-174-315-391

Asia

476 Li Bing Road
Zhangjiang Hi-Tech Park
Pudong New Area
Shanghai 201203
China
Tel. +86-21-6141-8064

Back to Top
Logo