Instructables 3d printing


Popular 3D Printing Projects - Instructables

Best DIY Camera Lens Caps V2.0 by dslrdiy in 3D Printing

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3D Printed Pop Its by MrErdreich in 3D Printing

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The Simply Impossible Puzzle by TheMadWrapper in 3D Printing

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PiBM PS/2 Model 25 - 3D Printing, Assembly, and Electronics by poprhythm in 3D Printing

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Penrose Triangle by NEW PEW in 3D Printing

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G Wagon - RC Scale Model by Rambros in 3D Printing

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3D Printed IMac G3 Mini - Fully Functional Hackintosh Powered by Intel NUC by GregO29 in 3D Printing

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A New Perspective on 3D Printing! by Caelestis Cosplay in 3D Printing

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Marblevator, Clouds. by gzumwalt in 3D Printing

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Repurpose Old Earphones to Capture 3D Printing Time-Lapses by NirL in 3D Printing

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A 3D Printed Windup Car Using a "Runaway Escapement" Speed Regulator. by gzumwalt in 3D Printing

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3D Printed Universal Drill Holder by Timbertime in 3D Printing

66 4.1K

Diy Tape Measure Yagi Antenna for Ham Radio by Mikiah in 3D Printing

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Memory Lamp by Banhammer in 3D Printing

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A 3D Printed Slinky Machine by gzumwalt in 3D Printing

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Hobby Lamp / Lampara Para Hobby by modelkitsdeluxe in 3D Printing

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Marblevator, "The Ferris Wheel at the Pumpkin Patch" by gzumwalt in 3D Printing

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WINTURER: a Portable NP-F Battery Charger Wind Turbine by adriancubas in 3D Printing

642 65K

3D Printed Wigglegram Lens (Sony E-mount / APSC) by scealux in 3D Printing

37 3.8K

Blastoise Humidifier by Fay3dlab in 3D Printing

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Tens'EGG'rity - Halloween - 3D Printed by seabirdhh in Decorating

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Faux Barbed Wire Choker and Bracelet - Flexible 3D Print by Penolopy Bulnick in 3D Printing

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Animatronic Robot by Nitin r in 3D Printing

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Ultimate (On a Budget) Home Vacuum by Icelandian in 3D Printing

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Life Sized Talking BMO From Adventure Time (that's Also an Octoprint Server!) by katzcreates in 3D Printing

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Forged Fabric Parts!!?. . With 3D Printed Compression Molds by JGJMatt in 3D Printing

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3D PRINT a STEAM TRAIN 🚂 With Live Camera Streaming and Wifi Controls by DIY Machines in 3D Printing

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Cut 3D Print Times in Half With Negative Volume Printing by MechanicalMashup in 3D Printing

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Are Expensive Nozzles OVERRATED? by diyperspective in 3D Printing

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Marblevator, Golf by gzumwalt in 3D Printing

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Egg Topper -Tinkercad basics by sigritom in 3D Printing

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Make an Ostrich Egg Lamp by alatorre in Reuse

Second Prize 41 7.1K

Jurassic Park Gate Remote Control by Fay3dlab in 3D Printing

Judges Prize 40 4.6K

Brush and Display Together: Camera Lucida for Light Strokes by RichardGreene in Digital Graphics

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Model Paint Shaker by Fay3dlab in 3D Printing

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Slidee: Non-motorized Automatic Camera Slider by Shivam Dehinwal in 3D Printing

Second Prize 108 6.3K

3D Printed Multi-Angle Drill Guide by Kartik_Nanduri in 3D Printing

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Smack Activated Cat Toy 🐈 by JGJMatt in 3D Printing

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Pet Bowl Riser - 3D Printing by garweb in Pets

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Silent Omni-Directional Desk Fan by JGJMatt in 3D Printing

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Tool for Making Soil Blocks (3D Printed) by DonnaCohn in Gardening

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Cat and Dog Selective Feeder by tomasdiazwahl in 3D Printing

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3D Printer Enclosure - Wood With Acrylic Windows by poprhythm in 3D Printing

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217416670000000000000000000000:1 Cycloidal Drive by ShirdelY in 3D Printing

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Altoid Arcade by AndrewDuong01 in 3D Printing

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3D Printed - V6 Internal Combustion Engine by aseeshpaulbandaru in 3D Printing

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MOTUS - Open-Source 3D Printed Robotic Arm by alatorre in 3D Printing

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Custom Color Art Board by cfb70 in 3D Printing

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Marblevator, Pick and Place, Version 3 by gzumwalt in 3D Printing

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Easy to Build 3D Printed RC Car - Dragon R1 by Rambros in 3D Printing

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3D Printing a 3D Printer Stand by vanweb in 3D Printing

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3D Printed Spool Storage by charlie-nino in 3D Printing

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Electromagnetic Launcher Prototype by eckwan in 3D Printing

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RC Car Upgrade Using 3D Printing by mechengdj in 3D Printing

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Telephone Booth - Indoor Greenhouse With Lights by FrauMartina in 3D Printing

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Desk Toy - How to Build a Mini Gumball Machine by BChang in 3D Printing

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Build Your Own Retrograde Clock! by JGJMatt in 3D Printing

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Miniature/Travel Checkers Set by SoccerStrong06 in 3D Printing

25 1.1K

Balrog Glowing Flames by Fay3dlab in 3D Printing

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3D Dog Artwork With Cardboard Upcycled Frame by Kbundred in Art

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Make Your Own 3D Printer for Under $60 Using Recycled Electronic Components with Instructables Design - 3DPrint.com

One of the obstacles to jumping headlong into the additive manufacturing milieu for many people is often the expense of the 3D printer itself. Further, for those intrepid, budding engineers, designers, makers, and artists, an initial foray might more reasonably and affordably involve using a less expensive and complex machine. Enter one Instructables contributor, “mikelllc,” who has designed a make-it-yourself 3D printer that is constructed largely from recycled electronic components.

Currently, only about 12.5% of all electronic waste, or “e-waste,” is recycled. Instead, the majority of cast-off electronic products — around 20 to 50 million metric tons per year worldwide — end up in incinerators or landfills. Many such products languishing in landfills can also release toxic chemicals into the air and soil, including high amounts of lead. So, repurposing electronic products makes great sense economically and ecologically.

The EWaste $60 3D Printer is inexpensive to make given that you can round up the necessary components and follow the maker’s step-by-step instructions, which are clear and detailed. The process, in short, involves schooling yourself on “how a generic CNC (Computer Numerical Control) system works” and then programming your printer-in-the-making to respond to G-code instructions. With the addition and calibration of a plastic extruder, the tuning of the driver power, and other well-outlined and described steps in the construction process, you end up with a “small footprint” 3D printer that is comprised of upwards of 80% recycled components — an eco-conscious and budget-friendly alternative to springing for a new and potentially costly 3D printer.

One of the major selling points of this design for a 3D printer is that not only do you end up with a usable machine at the end of the process, but that the process of building and programming the thing yourself also provides you with a solid tech-ed mini-course (or maxi-course for the completely uninitiated). What you need to get started are two standard CD/DVD drives from a used PC, a floppy disc drive from which you extract stepper rather than DC motors (you’ll need three stepper motors in all), a PC power supply, cables, female connectors, a heat-shrink tube, and some CNC electronics. There are some components — like a NEMA 17 stepper motor — that you’ll need to purchase new, but for the most part you’ll be going with used and recycled parts.

The Instructables page provides thorough instructions for everything from soldering the cables to the motors and doing the basic electrical work, installing and using Arduino printer control software, downloading firmware, configuring the motherboard, and so on. In the instance of components that are not accessible from previously used electronics, there are instructions and templates for making your own laser cut parts for the frame, which can be assembled without the use of glue.

The 3D printer uses 1.75 mm plastic filament, which is both easier to extrude and also much more flexible than 3 mm filament. Additionally, using the 1.75 mm filament means that you’ll require less power to run your machine, which is definitely earth-friendly, as is the use of PLA bio-plastic (as opposed to ABS). This maker is willing to be contacted for troubleshooting, and the project — and completely usable end result — seems worth the fairly complicated process.

Is this a project you’d think to undertake? Have you already? Let us know how you found the process, and what your results were, at the discussion forum for the EWaste $60 3D Printer at 3DPB.com!

Stay up-to-date on all the latest news from the 3D printing industry and receive information and offers from third party vendors.

Tagged with: 3d printer • diy 3d printer • ewaste • instructables • recycle 3d printer • recycled parts

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instruction how to work from scratch for beginners and dummies, how

looks like

Three-dimensional printing has become increasingly introduced into our daily lives. Thanks to new technologies, it has become possible to easily print from a small detail to a large building. The range of products is also pleasing - today you can find a lineup that includes both affordable devices and more expensive ones. But how to work with a 3D printer? This is a completely normal question that any beginner will have, it is for this reason that we will try to answer it as simply and accessible as possible.

What is a 3D printer and how does it work?

The 3D device consists of the printer itself and a computer that controls all processes. The principle of operation of such a design is to create 3D models by superimposing layers of liquid material. There are a large number of printer models - from large industrial ones to compact ones, but they all have the same principle of operation and component parts:

  • Extruder - the print head through which the thread passes. The head heats the thread to a semi-liquid state and evenly supplies the material to the working surface.
  • Work surface - a printing platform on which a 3D model is formed.
  • Motors - mechanisms responsible for the accuracy of movement and speed of printing.
  • Sensors are electronic devices that limit moving parts to specified coordinates.
  • The frame is the structure that connects all parts of the printer.

How a 3D printer works: features

Work with the aim of building a three-dimensional model begins with a sketch, which is created in a special program. After that, the software independently generates a plan for the movement of the print head and a print sequence. The 3D model is reproduced by strongly heating the plastic and distributing it evenly.

3D printers are used in many areas. Let's list some of them:

  • Architecture - creation of models of buildings.
  • Medicine - dental prosthetics, making models of organs for study.
  • Construction - production of houses using 3D printing technology.
  • Education - a visual aid for learning 3D printing.
  • Automotive - creation of tuning parts, prototype layouts and other products.

This is a small list of industries where 3D printing is actively used. Today, almost every entrepreneur and just an enthusiastic person can afford a printer.

The following printers are distinguished by design features:

  • RepRap - self-reproducing printers that can create their own copies.
  • DIY-kit - the device comes disassembled with instructions, the assembly of which will take a sufficient amount of time.
  • Completed - Models are delivered assembled and ready to use.
  • Commercial and Industrial - devices capable of printing metal, concrete, polymers and other materials.

How to use a 3D printer: tips for beginners, where to start

Mastering the technique of 3D printing is not difficult if you follow the recommendations and tips. Especially for those who plan to learn the basics of 3D modeling, an up-to-date list of questions and detailed answers to them has been prepared.

Printer Installation

To begin, you will need to carefully unpack the box and remove any stops. The next step is to install the printer on the surface using the building level. This will allow you to place the device as evenly as possible, which will provide better printing.

Note. Some 3D printers come with a level for installation.

Next, you will need to connect the printer to your computer and install the necessary drivers. The software disc comes with the 3D device.

Preparation for work

To get started, you need to calibrate the working surface - without this, printing quality products is impossible. This process is carried out automatically or manually. The attached instructions have detailed information on how to perform manual calibration.

Extruder patency test

The next important step is setting up the extruder. First of all, you will need to check its nozzle. If the printer has already been used, the nozzle should be cleaned of solidified particles that will interfere with the throughput of the material. Refueling the 3D printer The thread is fed into the extruder directly from the spool. But there is one caveat - for this you must first warm it up. To thread the thread, you will have to make a small effort in order to loosen the presser mechanism.

Working with models

Models can be created using a variety of 3D modeling programs. The process of manufacturing three-dimensional parts is creative, requiring careful preparation. The better and more detailed the model is drawn, the better the 3D layout will be at the output.

Start printing

After creating the model in the program and preparing the printer for work, you need to send the file for printing and wait for the result. The print speed varies depending on the printer model and specifications, as well as the media used.

Processing the finished product

3D printed products usually do not please the user with an ideal appearance: the parts have an uneven surface. But this is typical for models of 3D printers on FDM, SLA and DLP devices, which are distinguished by higher print quality. Owners of FDM printers should not despair - a simple processing of products will give products an attractive appearance and make the surface smooth.

Several powerful ways to post-process 3D printed parts:

  • Mechanical - carried out by sanding the surface with sandpaper or a special sponge for grinding.
  • Chemical - Surface treatment with aggressive solvents such as acetone and dichloroethane.
  • Mixed - In this case, the above two processing methods are used.

What are the possible errors and how to avoid them?

Even a novice can master the technology of 3D printing, but, despite this, the production of the first products causes excitement for the user. Simple operation, detailed instructions and recommendations on the Internet will allow everyone to deal with almost any printer model. But there are a few useful life hacks, the knowledge of which will help you avoid typical beginner mistakes:

  • Calibrate and test the 3D printer before starting work.
  • Be sure to use the correct file extension for quality printing.
  • Do not remove the finished product from the printer immediately after it has been processed: this may damage the part and cause defects.
  • If errors occur during the 3D printing process, try restarting the device - this usually helps.
  • If restarting the printer still does not help, try changing the settings or re-entering the model.
  • When assembling the 3D printing devices, follow the enclosed instructions carefully.
  • Use only the correct materials for your 3D printer.
  • Subscribe to useful 3D printing channels and articles.

Following the above tips will allow you to set up your 3D printer, get it ready for operation and, most importantly, print your first 3D products. Choose a model according to your budget and capabilities, and it will not be difficult to master the basics of 3D modeling and get the first details if you follow the instructions and recommendations.

  • March 21, 2021
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Get expert advice

The Complete Guide to 3D Printing [Part 2]

3D printing is used in a variety of industries, both for rapid prototyping and short-term production.

A key application of 3D printing in various industries is the rapid prototyping of new parts during R&D. No other technology has the capability to instantly produce plastic or metal parts - even in non-factory conditions.

3D printers can be used in-house by companies, while some businesses prefer to order 3D printed prototypes through service bureaus.

Medical

3D printing can be used to make medical components such as titanium implants and surgical guides (SLM), 3D printed prostheses (SLS, FDM) and even 3D bioprinted human tissues. Components for medical equipment and technology - X-ray machines, MRI, etc. - can also be made by 3D printing.

SLA and SLS technologies are also widely used in the dental industry for model making, prostheses and restorations.

Aerospace

The aerospace industry has become a major consumer of 3D printing technology because it can produce very light parts with an excellent strength-to-weight ratio. Examples include things as simple as cab bulkheads (SLS) and down to revolutionary engine components (SLM) such as the 3D printed fuel injector tip designed and manufactured by GE.

Cars

Automotive companies regularly use 3D printers to make one-off parts and repairs, as well as rapid prototypes. Common 3D printed automotive parts include brackets, dashboard components, and antennas (FDM).

More extreme examples include vehicles with large 3D printed metal structural components, such as early models from automotive startup Divergent.

Jewelry and art

3D printing technologies such as SLA are widely used (as an indirect fabrication process) in the production and repair of jewelry, while almost all types of 3D printers can be used to create art and sculpture.

Engineering

Advances in additive manufacturing with high quality workmanship have expanded the scope of applications in construction and architecture. Concrete 3D printing, which is a bit like FDM but with very wide nozzle extruders, plays an important role in this industry, but more common 3D printing technologies such as SLM can be used for products such as bridge structures.

3D printing file formats:

3D printing parts can be designed with standard CAD software, but 3D printers can only read certain file formats. There are four main file formats for 3D printing.

STL: The most common file format for 3D printers, STL contains part geometry information in the form of tessellated triangles. It does not contain information such as color, material, or texture. The file size is proportional to the detail, which can be a problem.

OBJ: Less common than STL, the OBJ file format encodes the geometry of a 3D model and can include curves and free-form surfaces in addition to tessellation. It can also contain color, material, and texture information, making it useful for full color processes.

3MF: Invented by Microsoft, 3MF is an XML-based format with small file sizes and a good level of error prevention. It has not yet been widely adopted, but is supported by companies such as Stratasys, 3D Systems, Siemens, HP, and GE.

AMF: The successor to the STL format, AMF is much more compact and allows you to tessellate both curved and flat triangles, making it much easier to encode parts of various shapes. Since its inception, the format has been slowly adopted.

3D printing settings and specifications:

3D printing uses specific terminology that may not be clear to beginners. These terms refer to printer settings and/or specifications that can affect how 3D printed parts turn out.

Infill

When making 3D printed parts, it may be necessary to specify an infill percentage, which refers to the internal density of the part. A low infill percentage will result in a mostly hollow part with minimal material holding the mold together; a high infill percentage will result in a stronger, denser, and heavier part.

Layer Height

Layer height, sometimes referred to as z-resolution, is the distance between one 2D part layer and the next. A smaller layer height means finer resolution (and higher possible level of detail) along the z-axis, i.e. top down. A low layer height is an indication of a high quality printer, but users can set a higher layer height for faster, more economical printing.

Print speed

The printer's print speed, measured in millimeters per second, indicates the speed at which the machine can process the source material. Like the layer height, this value can either be a measure of the printer's maximum speed or be user-defined: slower print speeds usually result in more accurate prints.

Print temperature

When applied to processes such as FDM, print temperature usually refers to the temperature of the hot end, the part of the print head that heats the thermoplastic filament. Some FDM printers are also equipped with a heated print bed, the temperature of which is specified by the manufacturer. In both cases, the temperature is usually controlled by the user.

Resolution

In 3D printing, resolution almost always refers to the smallest possible movement along the X and Y axes (width and depth) of either the laser beam (SLA, SLM, etc.) or the print head (FDM). This value is more difficult to measure than the height of the layer, and it is not always proportional to it.

Shells

Like wall thickness in injection molding, shell (or shell thickness) refers to the outer wall thickness of the 3D printed part. When 3D printing, users usually have to choose the number of shells: one shell = outer walls as thick as a 3D printer nozzle; 2 shells = twice the thickness, etc.

Color 3D printing:

Since 3D printing is primarily used as a prototyping tool, single color prints are sufficient for most applications. However, there are several options for color 3D printing, including high-end material inkjet printers, multi-extruder FDM printers, and post-processing options.

Inkjet Printing Technologies

Major 3D printing companies such as Stratasys, 3D Systems and Mimaki have developed 3D inkjet printers for materials and binders that can print 3D models in full color as well as 2D inkjet printers. However, these machines are expensive and the parts do not always have excellent mechanical properties.

Multi-extrusion

Several FDM 3D printers are equipped with two (or more) printheads, allowing you to simultaneously print on two spools of filament - different colors or even different materials - within the same print job. It's simple and affordable, but usually limited to two colors.

Filament replacement

Single extruder FDM 3D printer can produce multi-color prints. To do this, you need to pause printing at certain points and replace the spool of thread with a thread of a different color. This is a very slow method of applying color and does not allow precise control over where each color goes.

Adding color after printing

Many 3D printed parts can be dyed, tinted or painted after printing. While this adds another step to the process, it often strikes the best balance between quality and economy.

Post-Processing 3D Printed Parts:

Many 3D printed parts require at least some level of post-processing after leaving the print bed. This may include important processes such as the removal of supports, or additional cosmetic processes such as painting. Some processes apply to all or most 3D printing technologies, and some are specific to a particular technology.

Removing the support

3D printing technologies such as FDM and SLA require the installation of support structures (vertical posts between the printed layer and the part itself) to prevent the printed object from breaking during the manufacturing process.

These supports must be removed when the part is finished. Some printers, such as dual-extrusion FDM machines, can print dissolvable support structures, allowing the support structures to be easily detached from the part using liquid chemicals. Insoluble supports must be manually cut from the part, leaving a mark that may need to be sanded down.

Wash and remove powder

Some 3D printing technologies (such as SLA) leave sticky marks on parts, while others (SLM, SLS) may leave powder marks. In these cases, the parts must be washed - manually or with a special machine - or the powder removed with compressed air.

Heat treatment

Many key 3D printing technologies print parts from materials that are not yet in their final chemical state after leaving the printing mold. Such details are sometimes called "green".

Many 3D printed metal parts require heat treatment after printing to increase layer fusing and remove contaminants. And bonded inkjet 3D printers, for example, produce parts that need to be stripped and sintered after printing to remove resin bond layers from inside metal parts.

Some 3D printed resin parts require post-curing after printing to increase their hardness and make them usable.

Surface treatment

3D printed parts can be subjected to a wide variety of surface treatments, from textural treatments such as sanding and smoothing, to visual treatments such as painting and toning. Some technologies, such as FDM, can create a rather rough surface that requires sanding, while others, such as SLA, produce a much smoother surface.

Combination of 3D printing with other technologies:

3D printing does not have to be used as a separate process. Rather than being seen as a competitor to CNC machining and injection molding, it can actually complement these and other manufacturing processes.

Combination examples include:

  • 3D print the main body of the part and then CNC mill the thin parts to tighter tolerances;
  • 3D printed master pattern for investment casting or vacuum casting;
  • 3D print the part and then injection mold using injection molding.

There are hybrid manufacturing systems that combine 3D printing with other technologies. For example, Mazak's INTEGREX i-400 AM and DMG MORI's Lasertec DED can perform both 3D printing and CNC milling.

Will 3D printing replace other manufacturing processes?

Analysts have long speculated about whether 3D printing could replace other manufacturing processes, including:

  • Processing;
  • Moulding;
  • Casting.

However, despite the desire of AM equipment manufacturers to position 3D printing as an end-to-end manufacturing technology, in practice 3D printing is still limited to some specific manufacturing operations, especially the low-volume production of specific materials.

In some areas, 3D printing has certainly overtaken other processes. For example, rapid prototyping with inexpensive plastics like ABS now dominates 3D printing, as ABS is cheaper to print than machined. 3D printing also seems to have established itself as the ideal tool for making objects such as patient-specific titanium medical implants: the speed and geometric flexibility of 3D printing is hard to beat in these specific situations.

In addition, 3D printing is an ideal tool for making objects such as patient-specific titanium medical implants.

Despite this, processes such as CNC machining currently remain the best for producing high quality parts and prototypes from engineering materials such as POM, PEI, PPS and PEEK, with surface finishes far superior to 3D printing. . In addition, processes such as injection molding are still infinitely faster for mass production of simple plastic parts.

In addition, although additive manufacturing is one of the most significant technological advances in manufacturing, which allows it to take a stronger position in manufacturing in general, more established processes such as CNC and injection molding are also being improved to produce higher quality parts. .

3D printing will continue to take an increasing share of manufacturing jobs, but it will not completely replace other technologies.

What did 3D printing look like 10 years ago?

A decade ago, the nascent 3D printing industry was gearing up for what it believed was going to be a 3D printing revolution: a 3D printer in every home, allowing families to print new items they might need, such as a spare part for a refrigerator, a new toy for kids, or even components to build a second 3D printer.

In 2012-2014, FDM 3D printer manufacturers such as MakerBot actively promoted their 3D printers in the consumer market, trying to convince ordinary people that a 3D printer can improve their home life and work. However, it was clear that these companies were trying to exploit the novelty factor of 3D printing and that their products had no practical application; a 2012 MakerBot press release seems to prove it: Make an entire chess set at the touch of a button. Friends, classmates, colleagues and family members will see what you are doing and say "Wow!".

Just a few years later, this so-called 3D printing revolution clearly failed, and many 3D printer manufacturers began to rethink their goals, moving from consumer to professional and industrial markets, where there were more concrete (and profitable) applications of additive technology.

In addition, those who were already working in the professional and industrial fields - companies such as 3D Systems and Stratasys - began to try to destroy the idea of ​​​​3D printing as a prototyping technology, positioning it as a viable mass production tool (which, obviously, , could be more profitable for the 3D printing industry, as manufacturers would have to fill entire factories with 3D printers, buy 3D printer management software, and hire 3D printing consultants).

What will 3D printing look like in 10 years?

3D printing companies have abandoned the prospect of putting a 3D printer in every home. However, in 10 years, they can expect some form of additive manufacturing to appear in more factories.

Although there is less talk about 3D printing today than in 2012, the technology continues to gain momentum in the professional and industrial world.

According to a recent report, market research firm 3DPBM Research expects the value of additive metal manufacturing to rise from $1.6 billion in 2020 to $30 billion by 2030, and this is largely due to the repositioning of AM as a manufacturing tool and the development of more high-performance engineering materials. (That said, 3D printing will remain a valuable prototyping tool in many industries, and prototyping applications will benefit just as much from technological advances.)

However, not only metal AM is being developed. Technologies such as HP's Multi Jet Fusion have opened up new possibilities for plastic printing, and innovators such as Carbon have developed new high-speed processes in the photopolymerization category. Niche areas such as 3D bioprinting and micro 3D printing are also regularly opening up new opportunities, and composite 3D printing (such as continuous carbon fiber 3D printing) is also on the rise: IDTechEX predicts that by 2030, the market size of composite 3D printing will be $1. 7 billion

In short, 3D printing will gradually become a serious competitor to other manufacturing processes in many disciplines.

How to outsource 3D printing services?

Investments in 3D printing hardware and software are not suitable for all businesses, so many successful companies outsource their 3D printing needs to third parties, such as online 3D printing service bureaus (for one-time projects) or prototyping partners and production, such as 3ERP (for one-time projects or repeat orders).

When outsourcing 3D printing services, it is important to consider whether your business needs design and manufacturing services or just manufacturing services. (Keep in mind that a poorly executed 3D model may fail for 3D printing).

In general, though, ordering 3D printed parts from a third party is easier than ever. Many manufacturers can start 3D printing with just a digital 3D model, although more important projects may require a technical drawing to communicate additional information such as materials, colors, and tolerances.


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