00:02
Designed for additive manufacture.
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After completing this video,
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identify the various types of additive machines,
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use fusion inspection tools to validate a model,
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and understand the principles of
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additive manufacturing and support requirements.
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To get started in this video,
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we're gonna take a look at 3 different data sets,
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the FFF quadcopter assembly,
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the FFF quadcopter arm,
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and the SLS quadcopter.
00:32
We're gonna be focusing on 3D printing,
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and we're gonna talk about a couple of different types of 3D printers.
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as you're preparing for the certification,
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it will be important that you have your own
00:43
research and knowledge on different types of 3D printing available.
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There are many different types of machines on the market,
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and we won't be able to cover them all.
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So we're going to focus a little bit on some basics and common types of machines
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and the geometry that we think about when we're thinking about 3D printing.
01:01
first we've got the FFF quadcopter assembly.
01:05
FFF stands for fused filament fabrication.
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And this is also the same as an FDM machine.
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FDM or FFF are typically the desktop type machines that you see.
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They use a spool of material that gets fed into an extruder,
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melted and laid down onto a build plate.
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With this type of fabrication,
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what we're generally doing is we're building the part
01:28
up layer by layer in a vertical fashion.
01:31
This means that the orientation of your part is going to
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be imperative to the build strength as well as the quality.
01:38
There are many different types of 3D printers,
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filaments available,
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and configurations of those filaments.
01:44
So it is important to have a basic understanding of
01:46
some of the types of materials that are available.
01:50
a standard PLA material is going to be used,
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but oftentimes a PETG or an ABS type material,
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or on the softer spectrum,
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a TPU material can be used for different types of parts.
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But the main thing that we want to focus on here is the build orientation.
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When we think about an FDM or FFF machine,
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these oftentimes have breakaway supports that are used.
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But parts that can be designed without supports needed at all,
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oftentimes are printed at higher quality,
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less chance of imperfection or breaking during the
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removal process of all of the different supports.
02:24
So looking at a part like this,
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the FFF quadcopter arm,
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this part was designed as a single portion of a larger
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assembly to be printed on an FFF machine without any supports.
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This means that at the very bottom,
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we've got a large flat face that'll give us good adhesion to the build plate.
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And all of the other geometry is oriented that it
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can be printed in that vertical orientation without support material.
02:49
This is meant to have a quadcopter motor attached to it,
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and there's a small channel that's used for routing the cables and a couple
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of slots that can be used for zip ties to hold those cables down.
02:60
All the geometry is in that vertical orientation,
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meaning we don't need to have any support material in order to print this part.
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if we happen to change the orientation of the print,
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if we placed it in this orientation,
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this means all of the holes,
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any horizontal overhangs,
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and geometry like this rounded or fileted section down here
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would have to have some sort of support structure,
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because the 3D printer can't build out in open air.
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It also means that we would have poor adhesion
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to the build plate because we've got rounded sections.
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This print could be made on other types of 3D printers,
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And there are several other common types of 3D printers,
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which is a powder-based printer,
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SLA or Polyjet machines which use a liquid,
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and there are even metal type machines that use a metal powder and
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it uses some sort of adhesive and lasers to help cure the metal.
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So when we think about the part,
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we always have to think about the
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dedicated manufacturing method that we're planning for,
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because the way in which we build certain parts may require supports on one machine,
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but maybe not supports on another.
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Let's take a look at another example.
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The SLS quadcopter file is a part that was designed to be 3D printed as one piece,
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and it was done using SLS nylon.
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I'm going to go ahead and go into our bodies
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folder because there are several different bodies in this design.
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Body 60 is the component tray that isn't needed.
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When we look at the geometry of this part,
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there's some venting that was used to help
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airflow get through this area of the design,
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but still add some support structure to it.
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This geometry could not be printed with other types of machines.
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Uh FFF machine generally couldn't do this without the supports.
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An SLA liquid type machine would still need a support structure,
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and the part is generally going to be too large for that type of process.
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in the SLS type of printing,
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where we have a powder bed that gets cured,
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that powder bed is a self-supporting structure.
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This means we can get away with certain types of geometry
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that wouldn't be available on many other types of printers.
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a basic understanding on the differences between.
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Let's say an SLS printer,
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an FDM or FFF printer,
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and some of the other printers that are available on the market.
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When we look at the vast majority of 3D printers,
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it is going to be a bit overwhelming.
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So make sure that you at least focus on the FFF style of desktop 3D printers,
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the SLS powder bed style printers,
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the SLA or Polyjet style printers which are using a liquid sort of substrate.
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And then also understand that there are metal printers,
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there are other types like the HP Multijet fusion printers available
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that are going to be a little bit less common for the average user.
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when we are talking about 3D printing,
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we also need to keep in mind that these parts need to be sent out to a
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Depending on the requirements,
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the part may be converted to a mesh directly from Fusion.
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We can select the body or components in the browser,
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right click and select save as mesh.
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We also have a utilities option where we can select the Make 3D print button.
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these are going to both give us the same options,
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but they will default to certain settings.
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In the same as mesh option,
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we can prepare as a mesh,
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We can send it directly to a 3D print utility,
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or we can create a new setup in our additive manufacturing workspace.
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if I select print utility,
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I can send it to a bamboo print slicer.
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I can send it to one of the other print slicers I have available.
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I can even preview the mesh that's going to be generated,
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and I can go into other refinement settings.
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maybe I want higher refinement because I have a lot of small rounded corners,
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and I maybe want to have higher resolution,
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so that way the screw holes are going to
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be as good as possible for my manufacturing method.
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this will automatically send it to the 3D print utility of my choice,
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and it will not save an STL or a mesh file externally for me.
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you may find that you want to send a different file type,
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such as a step file.
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You can do that from your file export menu.
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And simply pick the file type you want.
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it'll use a fusion archive file,
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but we can export an STL,
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an OBJ or a 3MF file from here,
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or we can also scroll down and we can find a step file.
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Most 3D print utilities now will accept a step file,
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which is a solid body,
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And if you're sending it to a 3D print utility or if you're uploading it to a supplier,
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they may allow you to upload a parasolid file,
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You simply just need to check what file types are available for them.
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But just keep in mind that when you do export as a mesh file,
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make sure you double check your refinement settings
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because a low refinement setting is going to mean
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that the resolution of your PAP is going
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to be much lower than you originally intended.
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If you export a step file or one of the other neutral CAD format files,
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that'll include the solid geometry.
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this arc is still going to be a true arc,
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and it's not going to be made up of a bunch of small triangles.
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make sure you take a little bit of time to explore the different types of 3D printers
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and make sure that you understand at least the basics around
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the fused filament fabrication,
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the SLS nylon or powder-based systems,
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and the liquid systems that are available on the market for users today.
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And also make sure that you spend a little
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bit of time understanding things like print orientation,
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and whether or not parts are going to need support material.
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All those factors will come into play when
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you're designing your own parts for 3D printing,
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and it may just help you on the certification as well.
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