3D printer: Difference between revisions

Introduction

This article shortly introduces 3D printers and provides some advice on selecting a printer. The original article, created many years ago, listed many printers, but I stopped upgrading systematically around 2016. The old version is still around. There are no endorsements, since I only owned a RapMan (2010), a fabbster (given away), a Creality (2015, given away), four different Felix printers (1.0, 2.2, Pro2 and Tec4.1 (I still use the latter two), a Fokoos Odin-5 F-3 (2022, bought for 200 Euros on sale) and a Creality K1 Max. I also use Prusa mini and I3 printers in our fablab.

According to Wikipedia, retrieved 11 April 2023, 3D printing or additive manufacturing is the construction of a three-dimensional object from a CAD model or a digital 3D model.[1] It can be done in a variety of processes in which material is deposited, joined or solidified under computer control,[2] with material being added together (such as plastics, liquids or powder grains being fused), typically layer by layer.

3D printer as geek campfire (Source:[1])

See also:

• 3D printing (explains some principles).
• 3D food printing
• Fab lab (for a wider technical picture)
• 3D printers in education and fab labs in education (for a wider picture in education)
• Printer-specific articles: Felix, RapMan, and Fabbster
• Software (listed below)
• Hobby milling (an alternative subtractive technology)
• (Micro) Fablab TECFA, our own little gear
• Slicers and user interfaces for 3D printers

3D printing technology

The most popular 3D printing techniques are:

• Fused deposition modeling (FDM), also called Fused Filament Fabrication (FFF). A typical example of the first available low cost kit that required a few days of assembly was the RapMan. As of 2023, entry level printers are cheap (around 300 Euros) and are assembled fairly quickly. Consumer-grade quality machines cost around 1000.
• Stereolithography (SLA): “is a form of 3-D printing technology used for creating models, prototypes, patterns, and production parts in a layer by layer fashion using photopolymerization, a process by which light causes chains of molecules to link, forming polymers.[1] Those polymers then make up the body of a three-dimensional solid.” (Wikipedia, Aug. 2017). SLA machines use a laser to harden selected areas.
• DLP (Digital Light Processing) works, like SLA, with resin. As opposed to a laser that will solidify very specific areas, a DLP printer projects an image onto the pool of resin which then hardens each layer, one at a time.
• Selective laser sintering (SLS): “an additive manufacturing technique that uses a high power laser (for example, a carbon dioxide laser) to fuse small particles of plastic, metal (direct metal laser sintering), ceramic, or glass powders into a mass that has a desired 3-dimensional shape” (Wikipedia, retrieved 14 October 2011)
• Syringue-based systems like the early Fab@Home can print Epoxy (composites), ceramics or food and these materials are pushed down with a piston.

Most hobby 3D printers use FDM, i.e. an extruder (i.e. a kind of gun) that heats up plastic filament which is then deposited layer by layer. They can print different sorts of Polymers. In the early years, the two following plastics were popular.

• ABS (used for Legos and car parts) is solid, but warps when printed a room temperature. I.e. it is difficult to print objects that have a larger than 4cm footprint.
• PLA (polylactic acid) is made of starch (i.e. plants). It doesn't warp, but it was not very solid and started deforming (melting) at relatively low temperature. As of 2023, more solid PLA filaments are available.

As of 2015 a much wider range of 3D printer filaments are available, including PET-G, PET, Nylon, TPU, TPEs, and various PLA-particle composites.

The opposite of additive manufacturing is subtractive manufacturing that takes away material from an initial form. These alternative technologies include:

• Laser cutting, a fairly simple to use technique for creating "flat" 3D objects by cutting "sheets" like wood or plexiglass. One can create designs that involve sticking or gluing components together.
• Milling, a process where parts of an object (e.g. a cube) are removed by drilling. For example, parts of car motors are produced like this. Milling is a fairly dangerous process, however hobbyist models that carve out from plastic or wood are safe to use in a classroom for example.

Filement printer features you should you look for

Must have features:

• A strong extruder including a good filament intake system (you should be able to walk away from the printer and be sure that plastic is always extruded, even after 20 hours or printing). Newcomers don't often get the fact, that even a fairly small piece takes many hours to print !
• A good board and firmware (as above, there should be no mistakes, i.e. a print head that stops moving at some point)
• A heated platform up to 80 degrees at least
• Ability to print 0.1mm layers accurately

Nice to have features:

• Support for different nozzle sizes up to 0.8mm (easy changing plus useful information on supported nozzles and how to change them)
• Support for multiple types of plastic, in particular PLA and PET-G, but also some stronger plastics like ABS or Nylon (for some, this is a must-have feature). Some people also want to print with flexible polymers, i.e. TPU or TPE. That requires a direct extruder where the motor sits on top of the nozzle (i.e. so-called Bowden extruders are not very suitable for TPU and not suitable for TPE)
• Extrusion and printhead movement speeds as slow and as fast as possible. Typically the first layer should be printed at 10-15mm/s but prototype quality should be printable at 150mm/s.
• A heated chamber (or at least a closed box) for printing plastics that warp, e.g. ABS.
• Accuracy (both detail and movement) down to 0.1mm resolution if possible
• Two print heads (for printer either two color models or designs that need support. In the latter case, there exit soluble plastics.
• Included easy-to use printer control software
• Support for a good machine code generation software (i.e. a slicer). Most printers work with open source slicers but the vendor should nevertheless provide some good standard settings.
• Support for standard RepRap g-code (in order to avoid slicer software lock-in)
• Control hardware/software that allows to pause/resume a print and to manually extract filament.
• As many standard hardware parts as possible (this will allow for quick replacement) and allow you cope if the company goes out of business. This includes the control board.
• Use of open source software for controlling the printer. Except for very few exceptions, opensource solutions like Repetier Host are simply better since you can still use your printer after the company and its software go out of business
• Automated bed leveling or model correction. Adjusting the bed (1-2 sheets of paper distance from printhead to bed in every position) is something that beginners have trouble with.
• A wide printing area (as wide as the objects you plan to print). 25x25x25 is OK as of 2023.

Comparisons

Comparing 3D printers is very very difficult for several reasons:

• Some do better than others with respect to different sorts of objects. Do the benchmark pieces represent what you would like to print ?
• Calibration is essential. Only a real expert can get the most out of a machine.
• How do you weight various factors ? (Reliability, smoothness/accuracy, min. layer size, speed or less obvious stuff like does the first layer stick, warping, dealing with overhangs, stringing)
• How do you account for the interaction between slicing software and printers, and between slicing parameters and printers ?

On of the first serious comparisons was done by Make Mag in nov 2012. One of my printers (the Felixprinter 1.0) came out ok. Nevertheless the author complained about assembly that was more difficult than expected and glitches with some delivered parts (like calibration of the stepper motors) and he is right to do that. However, why compare a non-assembled printer with assembled ones. I bought mine assembled (400 Euros extra) and it worked out of the box! In addition, the testers used default settings of the slicer software. Had they selected a different profile they would have obtained widely different results. I was able to print a test design that failed without problems. The Make Mag test was serious, but far from perfect. - Daniel K. Schneider 17:53, 22 November 2012 (CET)

Do not trust marketing hype. In any case, filament printers do have inherent flaws that no design can solve. Only trust reputable online sites (most receive something in exchange for rewiewing). Also, understand that some cheap printers start degrading after a few weeks and that others have poor quality assurance (i.e. some machines work fine but others need to repaired when you open the box).

Fast 2023 FDM machines

I am looking into these models right now and may buy one. By the end of 2022 very fast "coreXY" FDM printers did appear on the market or were announce for Q2 or Q3 of 2023. An other options are IDEX printers where two extruders can work at the same time on copied or mirrored same objects. Since Summer 2023, fast "bed slingers" like the cheap Kobra 2 from Anycubic did appear.

Since I hate waiting a full day for a moderately large bag of LEGO or DUPLO compatible bricks I am interesting in getting one of these model and would print with a 0.6mm nozzle or larger.

Some of these printers may require minor modifications, e.g. better PEI print plates (e.g. read this for the Bambu) or better nozzles. All probably require verification and some tuning after the transport.