LOCTITE LOCTITE 3D MED9851 Resin
LOCTITE 3D MED9851 is a clear, high-performance resin designed for durable medical devices, featuring excellent tensile and flexural properties, and high impact strength. It meets key ISO 10993 standards for biocompatibility, functions at body temperature or higher, and has a good surface finish. Key technical specs include 40% elongation at break, 2,300 MPa Young’s Modulus, and 68°C heat deflection temperature.
- Meets critical ISO standards for biocompatibility
- Excellent tensile, flexural, and impact strength
- Functions well at body temperature or higher
List Price: | $430.00 |
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Price: | $430.00 |
Price: | $... |
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Est. In Stock: Mar 28th | |
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LOCTITE 3D MED9851 RESIN
Medical Resins Designed for Durability
LOCTITE MED9851™, a high-performance, clear material designed for impact-resistant medical device applications. With outstanding tensile and flexural physical properties, including excellent stiffness and toughness, this material ensures durability and reliability in various medical settings. Meeting ISO 10993-5, -10, & -23 standards for biocompatibility, LOCTITE MED9851 operates seamlessly at body temperature or higher, offering exceptional impact strength and surface finish.
Key Features of the PRODUCT:
- High modulus material
- Excellent tensile and flexural physical properties
- Capable of meeting ISO 10993-5, -10, & -23 standards for biocompatibility
- Parts can function at body temperature or higher
- Good impact strength and surface finish
Technical Specifications
- Cytotoxicity: Passed ISO 10993-5
- Irritation & Skin Sensitization: Pending ISO 10993-10
- Tests for Irritation: Passed ISO 10993-23
- Elongation at Break: 40%
- Young’s Modulus: 2,300 MPa
- Tensile Stress at Break: 45 MPa
- Izod Impact (Notched): 50 J/m
- Heat Deflection Temperature: 68°C
Please note: ISO & ASTM standard results are valid when using an approved Henkel-validated workflow.
Mechanical Properties | Measure Method | Green | Post Processed |
---|---|---|---|
Young’s Modulus (MPa) | ASTM D638 | 1600 – 1750[1] | 2100 – 2300[1] |
Tensile Stress at Yield (MPa) | ASTM D638 | 32 - 38[1] | 50 - 55[1] |
Elongation at Yield (%) | ASTM D638 | 4.4 – 4.6[1] | 4.6 – 4.8[1] |
Tensile Stress at Break (MPa) | ASTM D638 | 30 - 34[1] | 40 - 45[1] |
Elongation at Break (%) | ASTM D638 | - | 35-40[1] |
Izod Impact (Notched) (J/m) | ASTM D256 | 54 - 68[2] | 40 - 50[2] |
Shore Hardness (3s) (D) | ASTM D2240 | - | 80 – 81[3] |
Other Properties | Measure Method | Green | Post Processed |
---|---|---|---|
HDT at 0.455 MPa (°C) | ASTM D648 | 65 - 68 [4] | - |
HDT at 1.82 MPa (°C) | ASTM D648 | 52 - 57 [4] | - |
Water Absorption (24hr) (%) | ASTM D570 | 1.84 [5] | - |
Water Absorption (72hr) (%) | ASTM D570 | 3.82 [5] | - |
Solid Density (g/cm3) | ASTM D1475 | 1.18 [6] | 1.18 [6] |
Workflow:
Validated workflows need to be followed to achieve properties as provided in the TDS. Examples of validated workflow steps are listed below. Users should defer to the most current workflow information for the best results which can be found here
Printer Settings:
LOCTITE 3D MED9851 CL is formulated to print optimally on an industrial DLP printer. Read the safety data sheet carefully to get details about health and safety instructions. Recommended print parameters:
- Shake resin bottle well before usage
- Temperature: 20°C to 35°C
- Intensity: 3 mW/cm² to 8 mW/cm²
Questions
The data sheet says the coefficient of thermal expansion is “ 0,1 10⁻⁴ / K”. If I assume the European convention for comma rather than decimal point I would read this as 0.1 x 10⁻⁴. Normally CTE is expressed in units of 10⁻⁶ meters/meter. Is the CTE of this material really half that of aluminum and 1/10 of that of most nylons, 10 x 10⁻⁶? As a liquid, it would have the CTE of regular nylon but as it cools, the glass puts the nylon into severe strain, probably why it is difficult to print. Clearly a bed temperature and heated environment will be critical, and cooling should be gradual and uniform. But really the amazing fact is that this CTE is less than 1/2 that of Aluminum, 23.6x10⁻⁶ and nearly that of Titanium, 9.7x10⁻⁶! The plot of CTE over temperature is a necessary component of the spec sheet. Does water absorption cause the printed parts to crack? Thanks!
Using a stock Ender 3 Pro. What additional upgrades would be necessary to maximize print quality for NylonG?
how well can the white nylonG transmit light? As in, Will it allow me to illuminate the print with a light source on the inside? trying to avoid clear PETG and need a stiffer polymer, so despite the vulnerability to UV light, uncoated, this material was suggested to me
Does this filament need an enclosure to print properly?
The technical data sheet states a "linear mould shrinkage" of 0.3. 1) Does this mean 0.3%? 2) Does the Matter Control slicer software scale up my model by 0.3% in order to accommodate the shrinkage in the final print, or is this something I should account for manually? 3) Is there a recommended cooling / curing process for the NylonG material so that I know that after a certain amount of time, shrinkage is largely over?
Can you please explain what are the best practices to prevent white NylonG from getting yellowish after print?
does anyone know what the best support spacing is for top and bottom for z axis only?
Is there an approved annealing process for this filament? No matter how much magigoo i use chamber temp, i get minor warping (parts i'm printing take 24 hrs +). I would like to relieve the internal stresses to hopefully straighten my parts out.
Is this a pa6, 66, 12 or something different?
The data sheet says the tensile strength is 95 MPa using ISO 527. Other manufacturers publish 3 strength values: xy, yz, xz. as a 3D printed structure is non-isotropic. (Meaning the material strength properties are different in each direction). The weakest direction, I suppose, is the direction that tests layer adhesion. Can you give me a better idea of how the material was tested? Were printed test samples used or molded samples, etc...
Can a Ender 3 with Micro Swiss hotend and extruder print Nylon G with stock thermistor and heat canister?
We print straight out of our let it start dehydrating for about an hour or two at 75 c max setting I just set the time for 12 hours and after an hour or two we start our printers and we feed directly into our enclosed printers on garolite with magigoo pa and hardened nozzle all metal hotend and just let it print
First print we did was perfect at 260c bed at 75c. I’m using a carbon fiber print bed and magigoo PA adhesive. I am using an extremely modified Ender6 with a slice engineering mosquito magnum with a Bondtech DDX extruder. Seems to me the extruder is as important as any other settings as your Esteps must be perfect. My only dislike is the orange is not as bright as it shows in samples. Amazing filament.
How much does the spool weigh for .5kg/1.75 ?
For everyone talking this product down…Try HARDER!!!! It’s by far my favorite material and the finish is insane ONCE you figure it out lol..you will see a nice glitter finish and 0 layer lines…I went through rolls with of this stuff until I got it…TRY HARDER…I promise it’ll be worth it in the end…I print on a modded ender 3 with or w/o an enclosure sometimes, I’ve successfully printed “big” entire build volume models …trust me I was pissed AF for a long time until I figured it out lol…
You appear to no longer carry Dupont Zytel. How does this compare, especially with settings?
This filament have the same warping problem like Nylon X ??
I am trying to print apart using black NylonG. I have made 3 attempts so far and each time The part warps and one of the corners comes loose from the bed. With each attempt I make it further into the print but end up with the same result. I’m using a CR10s pro with no part cooling fan with printer in an enclosure and an internal temp of 35c inside enclosure. First attempt: Glass bed, @ 60c, nozzle 260c, NANO polymer adhesive from VisionMiner, printed with a brim and used recommended feeds recommended from MatterHackers. Second try: same as before but 80c on bed Third try: 90c bed temp, 25% feed rate on first layer, 50% second then 100% for remainder. I have used about 375g of material thus far. I am using 100% infill for this part which I’m share doesn’t help. Any recommendations?
I have never printed with nylon so, I am learning about it. Why do you need to dry it? Is it because it has a lot of moisture in it from the factory or do you have to do this every time?
Can the glass fibers fall out during printing or when you touch it like with Colorfabb XT-CF20, I'm really scared of breathing in or getting glass fiber splinters with this. The only hazard i see is a burn hazard on the safety data sheet.
Went through almost 2 spoils of nylon G now . I have a flashforge creator pro upgraded with all metal hot end and it still isn’t hot enough for good later adhesion . I printed at 40mm/s at 280c and had a decent print but layer adhesion just wasn’t there completely . At least for my Glock frame that is, it seems like you should really be printing this material at 280 plus to get the most out of this material , I even had it sit in the oven for 24 hours at 180c . It is somewhat strong but my PLA plus blows it out of the water as far as strength goes. Do you think I should print with an ender 3 to get better later adhesion since those can go to 300c ?
Is the 3kg weight the amount of material on the spool? What's the length?
Can this be printed safely in a standard office with standard ventilation?
I bought the printdry filament drying system, what would be the best temp to dry this at and for how long?
What is the percentage of glass fiber in the nylon?
I’d like to know this as well. I’ve purchased a reel, and if I had to guess based on other glass reinforced filaments I’ve tried, this stuff seems like around 10-15% at most. The filament is just too flexible for it to contain any more than that. In comparison, polymaker has a PA6 gf filament with 25% fiber content and it will barely bend at all without snapping.