MatterHackers MatterHackers PRO Series 3D Printing Filament Starter Pack 1.75mm
Introducing the MatterHackers PRO Series 3D Printing Filament Starter Pack—the materials bundle designed to save you money producing professional parts out of an extensive collection of different filaments. This discounted bundle is perfect for 3D makers interested in exploring a variety of filament options in digital fabrication or are already producing professional end-use parts in different materials. Made in the USA, our PRO Series is engineered with a dimensional tolerance of ± 0.02mm for consistent top quality print results. This bundle comes with the following from our 1.75mm PRO Series line: PLA, Tough PLA, ABS, PETG and Nylon.
| List Price: | $250.00 |
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| Price: | $250.00 |
| Price: | $... |
| Availability: | Currently Unavailable |
| Order Now: | Ships Monday Free U.S. Shipping |
This bundle contains a variety of PRO Series filaments in size 1.75mm. Manufactured in the USA to a tolerance of ± 0.02mm, all of our PRO Series materials work above the gold standard to deliver precise results.
PROVIDING PROFESSIONAL QUALITY AS THE STANDARD 3D PRINTING EXPERIENCE
Produce fine prints with an array of top quality materials using MatterHackers PRO Series 3D Printing Filament Starter Pack. Engineered with efficient, reliable production in mind, PRO Series creates a higher quality solution for 3D makers who want to use various professional materials for a variety of professional projects—all while saving a little extra on costs. Every spool manufactured under the MatterHackers PRO Series line is designed to provide consistent colors and uniform dimensional tolerances of ±0.02mm for the best end results that users can expect every time. If you are a hobbyist looking to elevate your 3D printing experience to the next level or an additive manufacturer looking for production-worthy digital fabrication materials, MatterHackers PRO Series 3D Printing Filament Starter Pack is here with an assortment of filament to consistently get any job done smoothly and accurately.
- MatterHackers PRO Series 3D Printing Filament Starter Pack includes
- 1 x PRO Series PLA 1.75mm (1kg)
- 1 x PRO Series Tough PLA 1.75mm (1kg)
- 1 x PRO Series ABS 1.75mm (1kg)
- 1 x PRO Series PETG 1.75mm (1kg)
- 1 x PRO Series Nylon 1.75mm (0.75kg)*
*Nylon must be dry before printing to ensure success. If you do not own a storage system to keep filament dry, check out our filament drying system here.
RIGOROUS REQUIREMENTS FOR TIGHT TOLERANCES
Here at MatterHackers, we strictly strive to deliver the top tier quality product you pay for. With MatterHackers PRO Series 3D printing filaments, you get the best-of-the-best dimensional accuracy of ±0.02mm for reliable results. Funds dedicated to filament supply add up, which is why MatterHackers works hard to ensure the material that makers invest their hard earned money in returns consistent fantastic print quality for projects such as end-use part production. Accuracy is crucial when creating parts through digital fabrication which is why our experts pay attention to exact filament ovality, strict coloration guidelines, and definitive chemical patterns during the materials manufacturing process. Produce precise, professional 3D printed parts using a variety of materials from MatterHackers PRO Series 3D Printing Filament Starter Pack.
TECHNICAL SPECIFICATIONS
MatterHackers PRO Series 3D printing filament is professional, high quality material manufactured with industry leading tolerances of ±0.02mm. Engineered to succeed above the gold standard, PRO Series filaments are the go-to materials for professional printing and end use parts.
- Recommended Extrusion Temperatures
- PLA: 205±15°C
- Tough PLA: 210±30°C
- ABS: 230±10°C
- PETG: 245±10°C
- Nylon: 240°C - 260°C
- Recommended Print Bed Temperatures
- PLA: May not be required (depending on bed surface). If used, set to 55±10°C
- Tough PLA: 60°C
- ABS: 90±10°C
- PETG: 75°C
- Nylon: 60°C
- Spool Dimensions (Aprox.)
- Total Diameter: 203mm
- Inner Hole Diameter: 52mm
- Width: 63mm
- True Diameter: 1.75mm ±0.02mm
- Made in the USA
LEARN MORE ABOUT 3D PRINTING WITH FILAMENT
Our goal is to help you succeed with your 3D printing experience which is why we have created many guides to help you create the highest quality 3D printed parts possible. Check out how to succeed below.
- How to Succeed When Printing with PLA
- How to Succeed When Printing with ABS
- How to Succeed When Printing with PETG
- How to Succeed When Printing with Nylon
- ABS Bed Adhesion Tips & Tricks
- Filament Comparison Guide
STREAMLINE YOUR 3D PRINTING EXPERIENCE WITH MATTERHACKERS
At MatterHackers we pride ourselves in offering various quality products for every maker on top of offering friendly service, advice, and support through our staff. Every day MatterHackers constantly works to include various products that streamline the 3D printing experience for makers of every experience level. Have a question about our MatterHackers PRO Series 3D Printing Filament Starter Pack? No problem. Feel free to give our friendly, knowledgeable staff a call.
Questions
This isn't a question, but MatterHackers doesn't offer any kind of feedback system, so here you go. This material is incredibly prone to warping! It's worse than abs, and more like polycarbonate. This is exacerbated by the fact the manufacturer recommends printing with 100% infill. Buyer beware, if your part won't print GREAT in abs, then don't even try this stuff. I'm happy with it otherwise, just thought they didn't put a strong enough warning on here.
If I used a water soluble support that I removed yourself before sending it in, would that work? Would the green state survive that? If I used ABS, could I use acetone to remove/lossen it?
What is the length or volume of filament included. I've always hated this whole buying by weight and with a filament that is 80% Stainless Steel, this spool being 3KG means nothing to me about how much I can print.
How much shrinkage should we expect post-production?
Can you use this material on the New Bambu Lab X-1 Carbon
hi, as i work as a jeweler and have access to sintering equipment is there a lower cost to buy the material without the sintering ticket or is it $465 either way?
Do you recommend printing at 100% infill?
Is there a secondary filament the has the same printing properties Ultrafuse 316L that can be used as scaffolding during printing process with a printer like the bambu labs p1s and the ams system?
What is the build volume on this material? How large of an object can I make?
What is the Thermal Conductivity of the material (W/m-K)?
If I choose to do the debinding and sintering myself. What will be the vapor production that escapes the part during heating? Is there anything that is not allowed to be released into the atmosphere?
Does it have limited manufacturing dimensions? Does it mean that large size parts, for example 300 x 300 mm, can be produced with it?
Should any holes/vacant areas in our parts be decreased in size by 19.82% (x and y) and 26.1% (z)? Would this end up with hole/space expanding to the originally desired size as material is removed?
Will this product (BASF Ultrafuse 316L Metal 3D Printing Filament) work with BCN3D Sigma R19 printer?
For 3D printers printing at an angle (e.g. 35-45 deg), should part shrinkage / adjustment be based upon the orientation of the final part in its intended form or the print direction?
Will this be available in less exotic materials? Regular old mild steel would sure be nice. A36, 1018...something with properties similar to that.
Is the final sintered product chemical free when exposed to heats below 1000f?
If I use this to make small gun parts or a pistol barrel will they deny my sintering ticket and treat me like a racist white male?
Can i use soluble support with this filament?
Will Matterhackers be offering BASF Ultrafuse 17-4 PH in the future?
Is the material weldable in its finished state?
What is the weight of the plastic spool that holes the filament?
I know a 0.6mm steel nozzle is optimal but would a 0.4mm nozzle work. How would using an 0.4mm nozzle affect prints?
I have a makerbot method printer, equpped with a labs extruder for third party materials, if paired with makerbot engineers consultation, would it bepossible to print this material succesfully in this printer?
1. If I print this material with a Pulse, would it be best to use an enclosure? 2. Can it print usable threads or would it be best to tap the holes after sintering?
Will the final product be able to hold pressure? Around 50 psi
the description says The filament contains 80percent metal and 20percent polymer. am i right? and i wonder by the meaning 80 percent and 20percent ... is this by mass or volume?
List of compatible printers? Or is it any Printer with a hardened nozzle, +100C Bed and +-230C Head, any other minimum requirements?
Hi, Could I print a metal, mold insert 100x100x30mm to be inserted into a standard injection mold. This core & cavity would need to meet tolerances of less than 0.1mm. Wouls you have any material strenght data of a 3D printed part. Please email me back, info@proplastics.ie
I have a tube furnace capable of sintering stainless powder. Is there a way to schedule a consult to determine what works to keep burned off plastic from fouling my vacuum system?
Can I use my Makerbot Replicator to print this material?
What would a good heated chamber temp be ?
How comparable in strength is this part compared to a machined part using 316l
Ultrafuse 316L yields a part that is between 96 and 100% dense (when removing the part infill as a variable) - The remaining pores are very small and uniformly distributed. Since they are virtually spherical, these pores are not responsible for crack initiation.
Mechanical properties approach that of machined (raw or cast material) but that depends heavily on design, print quality (including infill and warping) as well as the sintering processes itself (something that must be considered when designing for this material).
Approximate (not published) mechanical properties are:
Yield Strength of 180 MPa
Tensile strength approximately 500 MPa
Elongation of 50%, but that depends on the hardness after sintering (can vary, but averages at 120 HV10)
Sintered parts will always have poor fatigue response compared to cast parts. dgaylord has responded to this question saying that spherical pores are not responsible for crack initiation, but this is incorrect. It would be correct to say that spherical pores induce lower stress intensity than oblong pores, but they still concentrate stress. A part that is not 100% dense will NEVER have equivalent strength to a fully dense part, especially in fatigue (cyclic stress).
Furthermore, the grain structure of this material is likely to be very different from cast or drawn stock. The sintering process can create ultra-fine grain structure which creates incredibly hard, abrasion-resistant parts - but you sacrifice ductility and toughness. Abrasion-resistance sounds great, but with a rough surface finish, that benefit is essentially negated. Note that it is possible that the sintering facilities heat-treat the parts after processing, which could greatly affect the actual grain structure of delivered parts.
Regardless, unless you're designing parts that are approaching the safety factor limits for the material, a home gamer will never notice these issues.
Source: Materials Science PhD student
This is correct - a sintered part will differ from a part machined from stock, but in many cases/applications, the differences will be insignificant.
We have a universal testing machine and will be performing tensile and flexural tests (ASTM E8 & E855) on sintered 316L parts soon.