High Strength 3D Printer Filaments

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55 Products

Easy-Print PLA 3D Printer Filaments


Black	Blue

Gray	Green

Orange	Red

White	Yellow

The most commonly used 3D printing material, these PLA filaments make detailed parts at a low melting point, so they won’t warp as they cool, rarely clog nozzles, and don’t require a heated printer bed. They’re also unlikely to drip and produce plastic strings for a clean finished part. In general, they’re best for printing prototypes instead of load-bearing parts since they’re not as strong as ABS or as heat resistant as PEEK. Print them on a fused filament fabrication (FFF) 3D printer.

Filaments with an annealing temperature can be heat treated to make parts harder, stronger, and better at resisting heat. To anneal, heat your finished part to the listed temperature and then let it cool slowly.

Maximum exposure temperature is the point at which a printed part will begin to deform. Above this temperature, your part will start to lose structural integrity. Filaments that can be annealed are also rated for maximum temperature after annealing, which is the new maximum exposure temperature once that process completes.

Static Dissipative—Static-dissipative PLA filaments make parts that protect equipment from electrostatic shocks by diverting electrostatic discharges in a controlled way. They’re often used to create tool handles, tote trays, enclosures, and other parts that are used near sensitive electronics. To adjust the surface resistivity of your printed part, change the temperature of your printer’s extruder. As the extruder’s temperature increases, the printed part’s resistivity will decrease.

Tensile Strength—Tensile strength is the best measure of a filament's overall strength. Similar to the stress applied on a rope during a game of tug-of-war, it's the amount of pulling force a material can handle before breaking. A higher rating means a stronger filament. A tensile strength of 5,000 psi and above is considered good; 12,000 psi and above is excellent.

											Spool					Each
	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Surface Resistivity, ohm/sq.	Hardness	Max. Exposure Temp.	Annealing Temp.	Max. Temp. After Annealing	For Min. Nozzle Opening Dia., mm	Dia., mm	Dp., mm	Material	Wt., g		1-9	10-Up
PLA—Easy Print, Extra High Strength, High Strength







				Opaque Black

				1.75	190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N211	000000	000000


				2.85	190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N311	00000	00000




						Opaque Blue

						1.75	190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N217	00000	00000


						2.85	190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N317	00000	00000




								Opaque Gray

								1.75	190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N218	00000	00000


								2.85	190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N318	00000	00000




										Opaque Green

										1.75	190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N215	00000	00000


										2.85	190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N315	00000	00000




												Opaque Orange

												1.75	190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N216	00000	00000


												2.85	190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N316	00000	00000




														Opaque Red

														1.75	190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N213	00000	00000


														2.85	190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N313	00000	00000




														Opaque White

		1.75												190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N212	00000	00000


		2.85	190° to 230° C 374° to 446° F											0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N312	00000	00000




														Opaque Yellow

				1.75										190° to 230° C 374° to 446° F	0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N214	00000	00000


				2.85	190° to 230° C 374° to 446° F									0° to 70° C 32° to 158° F	9,500	—	Not Rated	60° C 140° F	110° C to 120° C 230° F to 248° F	130° C 266° F	0.4	200	91	Plastic	1,000	3502N314	00000	00000


				PLA—Easy Print, Extra High Strength, High Strength, Spark Resistant, Static Dissipative, Warp Resistant







														Opaque Black

														1.75	210° to 220° C 410° to 430° F	23° to 60° C 73° to 140° F	7,970	1× 10^7 to 1× 10^9	Not Rated	55° C 131° F	—	—	0.25	200	70	Plastic	750	3502N11	000000	00000


														2.85	210° to 220° C 410° to 430° F	23° to 60° C 73° to 140° F	7,970	1× 10^7 to 1× 10^9	Not Rated	55° C 131° F	—	—	0.25	200	70	Plastic	750	3502N12	000000	00000

UV-Indicating Easy-Print PLA 3D Printer Filaments

Beige to Orange

Often used to monitor UV exposure and test UV curing and sterilization equipment, parts made from these filaments change color when exposed to the sun or UV lights. Made from PLA, the most commonly used 3D printing material, they make detailed parts at a low melting point. As a result, they rarely clog nozzles, won’t warp as they cool, and don’t require a heated printer bed. They’re also unlikely to drip and produce plastic strings for a clean finished part. Print them on a fused filament fabrication (FFF) 3D printer.

Maximum exposure temperature is the point at which a printed part will begin to deform. Above this temperature, your part will start to lose structural integrity.

								Spool
	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Hardness	Max. Exposure Temp.	For Min. Nozzle Opening Dia., mm	Dia., mm	Dp., mm	Material	Wt., g		Each
PLA—Easy Print, Extra High Strength, High Strength







				Beige to Orange-Indicator

				1.75	190° to 230° C 374° to 446° F	25° to 60° C 77° to 140° F	6,620	Not Rated	58° C 136° F	0.4	200	65	Cardboard	1,000	4667N11	000000

Wear-Resistant Nylon 3D Printer Filaments

Black

Gray

Print tough, long-lasting parts that won’t scratch or wear out from constant motion and friction, such as gears and washers. You can even tap or drill the parts without them cracking or shattering.

Use these filaments with fused filament fabrication (FFF) printers. Because of their relatively high melting point, a heated printer bed is recommended. These filaments also emit fumes when printing, so it’s best to use them in an enclosed printer or to remove the fumes with a fume exhauster. Store them in a sealed container with a desiccant so they don’t absorb moisture in the air, which can make them unusable.

Maximum exposure temperature is the point at which a printed part will begin to deform. Above this temperature, your printed parts will start to lose structural integrity.

Carbon Fiber Filled—Carbon-fiber-filled nylon filaments make rigid parts that are difficult to bend and break. Their parts can also be threaded and machined more easily than the same filaments without any filler. However, they’re abrasive, so only use them with abrasion-resistant nozzles.

Fiberglass Filled—Fiberglass-filled nylon filaments make strong parts that are less prone to warping or shrinking than the same filaments without any filler. However, they’re abrasive, so only use them with abrasion-resistant nozzles.

Nylon 6/66—Nylon 6/66 filaments are the strongest nylon filaments without a filler, but may warp while cooling.

								Spool
	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Hardness	Max. Exposure Temp.	For Min. Nozzle Opening Dia., mm	Dia., mm	Dp., mm	Material	Wt., g		Each
Nylon—Extra High Strength, High Strength, Wear Resistant Nylon 6/66







				Opaque Black

				1.75	255° to 275° C 491° to 527° F	60° to 70° C 140° to 158° F	8,700	Durometer 60D (Medium)	85° C 185° F	0.25	200	75	Plastic	750	3483N1	000000


				Carbon Fiber-Filled Nylon—Extreme Strength, High Strength, Impact Resistant, Wear Resistant







								Opaque Black

								1.75	280° to 300° C 535° to 570° F	50° C 122° F	15,225	Not Rated	215° C 419° F	0.4	200	65	Cardboard	500	3483N6	00000


								Fiberglass-Filled Nylon—Extra High Strength, High Strength, Wear Resistant Nylon 6







												Opaque Gray

												1.75	280° to 300° C 536° to 572° F	25° to 50° C 77° to 122° F	11,950	Not Rated	70° C 158° F	0.4	250	117	Cardboard	2,000	3483N32	000000


												2.85	280° to 300° C 536° to 572° F	25° to 50° C 77° to 122° F	11,950	Not Rated	70° C 158° F	0.4	250	117	Cardboard	2,000	3483N33	000000

UV- and Impact-Resistant ASA 3D Printer Filaments

Black

Blue

Gray

White

Best for outdoor use, parts made from these ASA filaments are UV resistant, so they won't warp or crack from prolonged sun exposure. They’re also durable, so they absorb impact without breaking and won’t degrade when heated.

Use with fused filament fabrication (FFF) 3D printer. These filaments have a high melting point and must be printed onto a heated bed. Without it, parts will cool too quickly and warp. These filaments also release fumes as they are printed, so use an enclosed printer or a fume exhauster to ventilate them.

Maximum exposure temperature is the point at which a printed part will begin to deform. Above this temperature, your printed parts will start to lose structural integrity.

							Spool, mm
	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Max. Exposure Temp.	For Min. Nozzle Opening Dia., mm	Dia.	Dp.	Wt., g	Choose a Color		Each
ASA



		1.75	235° to 255° C 455° to 491° F	90° to 110° C 194° to 230° F	6,520	95° C 203° F	0.4	200	75	1,000	Black, Blue, Gray, White	1317N541	000000


		2.85	235° to 255° C 455° to 491° F	90° to 110° C 194° to 230° F	6,520	87° C 188° F	0.4	198	78	1,000	Black, White	1317N548	00000

Steam-Resistant High-Temperature Polysulfone 3D Printer Filaments


	Beige

Sterilize your printed parts without them expanding, deforming, or weakening. These polysulfone filaments resist steam and heat, so you can sterilize parts in an autoclave. They also can be sterilized with ethylene oxide, radiation, plasma, dry heat, and cold sterilization methods. Print these filaments on a fused filament fabrication (FFF) 3D printer. Because of their high melting points, you'll need an all-metal extruder and heated printer bed to reach their minimum printing temperature. Without the heated printer bed, parts will cool too quickly and warp.

Maximum exposure temperature is the point at which a printed part will begin to deform. Above this temperature, your part will start to lose structural integrity.

								Spool
	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Hardness	Max. Exposure Temp.	For Min. Nozzle Opening Dia., mm	Dia., mm	Dp., mm	Material	Wt., g		Each
Polysulfone—Extra High Strength, High Strength, High Temperature, Steam Resistant, Warp Resistant







				Semi-Clear Beige

				1.75	350° to 380° C 662° to 716° F	140° to 160° C 284° to 320° F	10,730	Not Rated	172° C 342° F	0.4	198	42	Plastic	500	3489N36	0000000

High-Strength Impact-Resistant Polycarbonate 3D Printer Filaments

Create strong, durable parts that carry heavy loads and absorb blows and other impact without cracking or breaking. Made of polycarbonate, these filaments are stronger and resist heat better than other impact-resistant filaments, such as those made from ABS or ASA.

Use with a fused filament fabrication (FFF) 3D printer. These filaments have a high melting point and must be printed onto a heated bed. Without it, parts will cool too quickly and warp. These filaments also release fumes as they are printed, so use an enclosed printer or a fume exhauster to ventilate them.

Maximum exposure temperature is the point at which a printed part will begin to deform. Above this temperature, your printed parts will start to lose structural integrity.

Carbon Fiber Filled—Carbon-fiber-filled polycarbonate filaments make rigid parts that are difficult to bend and break. Parts made from these filaments can also be threaded and machined more easily than parts made from polycarbonate filaments without a filler. Carbon-fiber-filled filaments are abrasive, so you should use them with an abrasion-resistant nozzle.

Fiberglass Filled—Fiberglass-filled polycarbonate filaments make parts that are less likely to warp or shrink than parts made from polycarbonate filaments without a filler. Fiberglass-filled filaments are abrasive, so you should use them with an abrasion-resistant nozzle.

Static Dissipative—Static-dissipative filaments make parts that protect equipment from electrostatic shocks by diverting electrostatic discharges in a controlled way. Use them to create tool handles, tote trays, enclosures, and other parts that are used near sensitive electronics. To adjust the surface resistivity of your printed part, change the temperature of your printer’s extruder. As the extruder’s temperature increases, the printed part’s resistivity will decrease.

UL 94 V-0—UL 94 V-0 rated filaments meet strict flammability standards. Use them to create holders, guards, housings, and other parts that protect sensitive, flammable equipment and machinery.

									Spool
	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Surface Resistivity, ohm/sq.	Hardness	Max. Exposure Temp.	For Min. Nozzle Opening Dia., mm	Dia., mm	Dp., mm	Material	Wt., g		Each
Polycarbonate—Extra High Strength, High Strength, Highly Absorbent, Impact Resistant







				Opaque Black

				1.75	280° to 310° C 536° to 590° F	110° to 120° C 230° to 248° F	8,990	—	Durometer 84D (Hard)	135° C 275° F	0.4	195	40	Plastic	500	1317N322	000000


				Carbon Fiber-Filled Polycarbonate—Extra High Strength, High Strength, Highly Absorbent, Impact Resistant







								Opaque Black

								1.75	260° to 280° C 500° to 535° F	80° to 100° C 175° to 210° F	10,580	—	Not Rated	115° C 245° F	0.4	195	55	Plastic	750	1317N353	00000


								2.85	260° to 280° C 500° to 535° F	80° to 100° C 175° to 210° F	10,580	—	Not Rated	115° C 245° F	0.4	195	55	Plastic	750	1317N354	00000


								Polycarbonate—Extra High Strength, High Strength, Highly Absorbent, Impact Resistant, Moisture Resistant, Spark Resistant, Static Dissipative







												Opaque Black

												1.75	260° to 300° C 500° to 572° F	110° to 120° C 230° to 248° F	9,860	1× 10^7 to 1× 10^9	Rockwell R125 (Hard)	135° C 275° F	0.4	200	75	Plastic	750	3481N15	000000


												Fiberglass-Filled Polycarbonate—Extra High Strength, Flame Retardant, High Strength, Impact Resistant UL 94 V-0







																Opaque Black

																1.75	280° to 330° C 536° to 626° F	80° to 100° C 176° to 212° F	5,300	—	Not Rated	124° C 255° F	0.6	200	55	Plastic	700	4663N11	00000


																2.85	280° to 330° C 536° to 626° F	80° to 100° C 176° to 212° F	5,300	—	Not Rated	124° C 255° F	0.6	200	55	Plastic	700	4663N12	00000

Chemical-Resistant PPSU 3D Printer Filaments

Off-White

Fabricate custom bottles, packaging, and other parts for chemical processing. Made of PPSU, these filaments won’t break down even after prolonged exposure to virtually any acid, base, or solvent. They also stand up to oil and fuel, so they’re sometimes made into automotive parts. Because they have a low density and won’t transfer electricity, they make parts that are lightweight and protect components from electric currents. These filaments are easy to store too, since they resist absorbing water. Rated UL 94 V-0, they meet flammability standards.

Print these filaments on a fused filament fabrication (FFF) 3D printer. Due to its high melting point, PPSU is more difficult to print than most other materials. You need an all-metal extruder and a heated printer bed to reach its minimum printing temperature. After printing, anneal your part in an oven for 2 to 4 hours to reach its maximum strength, temperature, and ability to resist chemicals.

Maximum exposure temperature is the point at which a printed part will begin to deform. Above this temperature, your part will start to lose structural integrity.

									Spool
	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Hardness	Max. Exposure Temp.	Annealing Temp.	For Min. Nozzle Opening Dia., mm	Dia., mm	Dp., mm	Material	Wt., g		Each
PPSU—Chemical Resistant, Extra High Strength, Flame Retardant, High Strength, Moisture Resistant, Ultra Absorbent UL 94 V-0







				Opaque Off-White

				1.75	390° to 410° C 734° to 770° F	140° to 160° C 284° to 320° F	7,970	Rockwell R110 (Hard)	180° C 200° C	80° to 130° C 176° to 266° F	0.4	200	40	Plastic	500	4271N7	0000000

Impact-Resistant ABS 3D Printer Filaments


	Black

Bumps, scrapes, and falls won’t damage these tough ABS filaments. Known for their durability, they absorb impact without cracking or breaking, and won’t degrade when heated. Use them to print tool handles, storage cases, and other parts that are handled or dropped frequently. These filaments are a good place to start if you’re experimenting with printing impact-resistant parts.

Maximum exposure temperature is the point at which a printed part will begin to deform. Above this temperature, your printed parts will start to lose structural integrity.

Carbon Fiber Filled—Carbon-fiber-filled ABS filaments make rigid parts that are difficult to bend and break. Their parts can also be threaded and machined more easily than ABS filaments without a filler. Carbon-fiber-filled filaments are abrasive, so you should use them with an abrasion-resistant nozzle. They will wear out other nozzles.

ABS/Polycarbonate—For heavy impact, use ABS/polycarbonate filaments. The polycarbonate adds strength to printed parts.

UL 94 V-0—Filaments rated UL 94 V-0 meet strict flammability standards. Use them to create holders, guards, housings, and other parts that protect sensitive, flammable equipment and machinery.

								Spool, mm
	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Surface Resistivity, ohm/sq.	Max. Exposure Temp.	For Min. Nozzle Opening Dia., mm	Dia.	Dp.	Wt., g	Color		Each
ABS—Extra High Strength, High Strength, Highly Absorbent, Impact Resistant, Moisture Resistant, Spark Resistant, Static Dissipative



		1.75	220° to 240° C 428° to 464° F	100° to 110° C 212° to 230° F	8,410	1× 10^7 to 1× 10^9	97° C 207° F	0.4	200	75	750	Black	3481N13	000000


		2.85	220° to 240° C 428° to 464° F	100° to 110° C 212° to 230° F	8,410	1× 10^7 to 1× 10^9	97° C 207° F	0.4	200	75	750	Black	3481N14	00000


		ABS—UL 94 V-0—Extra High Strength, Flame Retardant, High Strength, Highly Absorbent, Impact Resistant, Moisture Resistant



				1.75	220° to 240° C 428° to 464° F	100° to 110° C 212° to 230° F	6,520	—	95° C 203° F	0.4	200	75	750	Black	3665N411	00000


				2.85	220° to 240° C 428° to 464° F	100° to 110° C 212° to 230° F	6,520	—	95° C 203° F	0.4	200	75	750	Black	3665N412	00000


				ABS/Polycarbonate—UL 94 V-0—Extra High Strength, Flame Retardant, High Strength, Impact Resistant



						1.75	265° to 285° C 509° to 545° F	110° to 120° C 230° to 248° F	8,700	—	125° C 257° F	0.4	200	75	750	Black	3665N15	00000


						Carbon Fiber-Filled ABS—Extra High Strength, High Strength, Highly Absorbent, Impact Resistant



								1.75	220° to 240° C 428° to 464° F	100° to 110° C 212° to 230° F	6,670	—	76° C 169° F	0.4	195	55	750	Black	1317N311	00000


								2.85	220° to 240° C 428° to 464° F	100° to 110° C 212° to 230° F	6,670	—	76° C 169° F	0.4	195	55	750	Black	1317N312	00000

Dremel 3D Printer Filaments

Build parts and prototypes from these filaments using Dremel fused filament fabrication (FFF) 3D printers. An RFID tag on the spool communicates with your printer, automatically adjusting it to the correct temperature and print speed for the filament material and notifying you when the filament is running out.

Maximum exposure temperature is the point at which a printed part will begin to deform. Above this temperature, your printed parts will start to lose structural integrity.

PLA


Black	Blue

Green	Orange

Red	White

Clear

PLA filaments are the most commonly used in 3D printing. PLA is easy to use; it rarely clogs nozzles, doesn’t require a heated printer bed, and prints at a low temperature—meaning parts won’t warp while cooling. It produces string-free parts, so you can use it to print with a high level of detail. Less durable and more sensitive to heat than ECO-ABS, PLA is better for printing prototypes than end-use parts.

						Spool, mm
Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Max. Exposure Temp.	For Min. Nozzle Opening Dia., mm	Dia.	Dp.	Wt., g	Choose a Color		Each
1.75	200° to 230° C 395° to 445° F	35° C 95° F	6,620	60° C 140° F	0.25	180	55	750	Black, Blue, Green, Orange, Red, White, Clear	3653N4	000000

Eco-ABS


Black	White

ECO-ABS is less brittle and more impact resistant than PLA, so these filaments are good for printing parts that are frequently handled, dropped, or heated. They are, however, a little more high maintenance—parts may warp during cooling, so they require a heated printer bed.

							Spool, mm
Mfr. Model No.	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Max. Exposure Temp.	For Min. Nozzle Opening Dia., mm	Dia.	Dp.	Wt., g	Color		Each
ECO-BLA-01	1.75	190° to 240° C 374° to 464° F	60° C 140° F	8,410	63° C 145° F	0.2	181	55	750	Black	3653N23	000000
ECO-WHI-01	1.75	190° to 240° C 374° to 464° F	60° C 140° F	8,410	63° C 145° F	0.2	181	55	750	White	3653N24	00000

Nylon

Black

Nylon resists scratches and wear, and is often used to create parts that encounter constant friction such as gears or bearings. Nylon parts also won’t crack or shatter when they’re drilled or tapped. Exposure to humidity makes these filaments brittle and unusable, so they need to be stored in a sealed container with a desiccant. Like ECO-ABS, parts can warp during cooling and need a heated printer bed. Make sure your printer is connected to a ventilation system, as nylon emits fumes during printing.

							Spool, mm
Mfr. Model No.	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Max. Exposure Temp.	For Min. Nozzle Opening Dia., mm	Dia.	Dp.	Wt., g	Color		Each
DF45-NYP-B	1.75	230° to 250° C 446° to 482° F	80° C 176° F	7,540	155° C 311° F	0.4	180	55	500	Black	3653N12	000000

PETG

Clear

PETG is more moisture resistant than ECO-ABS, making it a great choice for printing parts for use in humid or wet environments. Generally, PETG’s other properties fall somewhere between those of PLA and ECO-ABS. It’s more flexible and durable than PLA, but less so than ECO-ABS. It’s harder to print than PLA because it requires a heated printer bed, but easier to print than ECO-ABS. PETG filaments should be kept in a sealed container with a desiccant.

							Spool, mm
Mfr. Model No.	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Max. Exposure Temp.	For Min. Nozzle Opening Dia., mm	Dia.	Dp.	Wt., g	Color		Each
PETG-TRA-01	1.75	240° to 260° C 464° to 500° F	80° C 175° F	7,250	84° C 183° F	0.2	181	55	750	Clear	3653N25	000000

Ultra-Strength High-Temperature PAEK 3D Printer Filaments

Beige

Parts made from these PAEK filaments, a family of materials that includes PEEK and PEKK, remain strong in high temperatures and hold up to wear from repeated use. They don’t degrade when exposed to most chemicals, so they’re often used to print parts for demanding chemical processing applications. Print these filaments on a fused filament fabrication (FFF) 3D printer. Because of their high melting point, you'll need an all-metal extruder and heated printer bed to reach their minimum printing temperature. Without the heated printer bed, parts will cool too quickly and warp.

Maximum exposure temperature is the point at which a printed part will begin to deform. Above this temperature, your printed parts will start to lose structural integrity.

Annealing is the process of heating prints to a specific annealing temperature and then slowly allowing them to cool. This makes the finished print harder, stronger, and better at resisting heat. Maximum temperature after annealing replaces the maximum exposure temperature once this process has been completed.

Fiberglass Filled—Fiberglass-filled PEEK filaments make stronger parts that are less likely to warp and shrink than unfilled PEEK filaments. Since they’re abrasive, you should only use them with an abrasion-resistant nozzle.

										Spool
	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Hardness	Max. Exposure Temp.	Max. Annealing Temp.	Max. Temp. After Annealing	For Min. Nozzle Opening Dia., mm	Dia., mm	Dp., mm	Material	Wt., g		Each
PEEK—Extreme Strength, High Strength, High Temperature, Ultra Strength, Warp Resistant, Wear Resistant







				Opaque Beige

				1.75	375° to 410° C 707° to 770° F	130° to 145° C 266° to 293° F	14,500	Durometer 85D (Hard)	140° C 284° F	140° C 284° F	230° C 446° F	0.4	195	40	Plastic	500	3489N22	0000000


				Fiberglass-Filled PEEK—Extreme Strength, High Strength, High Temperature, Ultra Strength, Warp Resistant, Wear Resistant







								Opaque Beige

								1.75	375° to 410° C 707° to 770° F	130° to 145° C 266° to 293° F	13,050	Durometer 86D (Hard)	260° C 500° F	140° C 284° F	315° C 599° F	0.4	195	40	Plastic	500	3489N21	000000

Moisture-Resistant Polyester 3D Printer Filaments

Black

Clear

Parts printed with these polyester filaments absorb less moisture than other types of plastic, making them ideal for use in wet or humid environments. They are more durable and flexible than PLA, and easier to print than ABS. Use these filaments with fused filament fabrication (FFF) 3D printers, and print onto a heated print bed. Printing onto a cool surface causes the molten filament to change temperature rapidly, which can warp your designs. Although finished parts are moisture-resistant, these filaments are sensitive to humidity, and should be stored in a dehumidifying cabinet or a sealed container with desiccant for the best printing quality.

Maximum exposure temperature is the point at which a printed part will begin to deform. Above this temperature, your printed parts will start to lose structural integrity.

Carbon Fiber Filled—Carbon-fiber-filled PETG is often used to make rigid parts that are difficult to bend and break. Finished parts are easier to thread and machine than unfilled parts. Because these filaments are abrasive, use them only with abrasion-resistant nozzles.

PETG—PETG contains glycol, so it is less brittle and easier to print than PETT and PCTG.

PCTG—PCTG is more impact resistant than PETG and holds up to a wide range of acids and bases without breaking down. It is often used for printing parts that will be exposed to chemicals and oils.

Static Dissipative—Static-dissipative filaments make parts that protect equipment from electrostatic shocks by diverting electrostatic discharges in a controlled way. Create tool handles, tote trays, enclosures, and other parts that are used near sensitive electronics. To adjust the surface resistivity of your printed part, change the temperature of your printer’s extruder. As the extruder’s temperature increases, the printed part’s resistivity will decrease.

Antistatic—Antistatic filaments make parts that prevent the buildup of static electricity. This helps prevent the buildup of dust or fibers on the surface of your finished part. However, they are not as effective at preventing electrostatic discharge as static-dissipative filaments.

									Spool
	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Surface Resistivity, ohm/sq.	Hardness	Max. Exposure Temp.	For Min. Nozzle Opening Dia., mm	Dia., mm	Dp., mm	Material	Wt., g		Each
PCTG—Chemical Resistant, Extra High Strength, High Strength, Highly Absorbent, Impact Resistant, Moisture Resistant







				Semi-Clear

				1.75	250° to 270° C 482° to 518° F	70° to 80° C 158° to 176° F	5,510	—	Not Rated	70° C 158° F	0.25	200	68	Plastic	1,000	3462N511	000000


				2.85	250° to 270° C 482° to 518° F	70° to 80° C 158° to 176° F	5,510	—	Not Rated	70° C 158° F	0.25	200	68	Plastic	1,000	3462N512	00000


				PETG—Extra High Strength, High Strength, Highly Absorbent, Moisture Resistant, Spark Resistant, Static Dissipative







								Opaque Black

								1.75	230° to 260° C 446° to 500° F	60° to 90° C 140° to 194° F	7,250	1× 10^7 to 1× 10^9	Rockwell R110 (Hard)	75° C 167° F	0.4	200	75	Plastic	750	3667N11	000000


								2.85	230° to 260° C 446° to 500° F	60° to 90° C 140° to 194° F	7,250	1× 10^7 to 1× 10^9	Rockwell R110 (Hard)	75° C 167° F	0.4	200	75	Plastic	750	3667N12	000000


								Carbon Fiber-Filled PETG—Antistatic, Extra High Strength, High Strength, Moisture Resistant, Spark Resistant







												Opaque Black

												1.75	230° to 260° C 446° to 500° F	60° C 140° F	8,120	1× 10^9 to 1× 10^12	Not Rated	77° C 170° F	0.4	200	60	Plastic	750	3462N1	00000


												2.85	230° to 260° C 446° to 500° F	60° C 140° F	8,120	1× 10^9 to 1× 10^12	Not Rated	77° C 170° F	0.4	200	60	Plastic	750	3462N11	00000

High-Temperature PEI 3D Printer Filaments

Gold

Beige

Often used to make parts that will be used near ovens, engines, and other hot machinery, these PEI filaments remain strong and rigid in temperatures that would soften most plastic. They’re a lightweight alternative to machined metal parts. Print these filaments on a fused filament fabrication (FFF) 3D printer. Because of their high melting points, you'll need an all-metal extruder and heated printer bed to reach their minimum printing temperature. Without the heated printer bed, parts will cool too quickly and warp.

Maximum exposure temperature is the point at which a printed part will begin to deform. Above this temperature, your part will start to lose structural integrity.

								Spool
	Dia., mm	Printing Temp.	For Printer Bed Temp.	Tensile Strength, psi	Hardness	Max. Exposure Temp.	For Min. Nozzle Opening Dia., mm	Dia., mm	Dp., mm	Material	Wt., g		Each
PEI—Extra High Strength, High Strength, High Temperature, Warp Resistant







				Opaque Gold

				1.75	370° to 390° C 698° to 734° F	120° to 160° C 248° to 320° F	8,120	Durometer 85D (Hard)	208° C 406° F	0.4	195	40	Plastic	500	3489N24	0000000


				PEI—Extra High Strength, High Strength, High Temperature, Highly Absorbent, Moisture Resistant, Warp Resistant







								Semi-Clear Beige

								1.75	350° to 380° C 662° to 716° F	140° to 160° C 284° to 320° F	7,830	Durometer 85D (Hard)	158° C 316° F	0.4	195	40	Plastic	500	3489N25	000000