As you work to develop CAD fluency, which means to be able to do your CAD work quickly and accurately, it helps to have a good CAD process. Now, a good CAD process always starts with understanding the purpose for the CAD work. In other words, understanding the job that needs to be done. Now in the product development process, we have a variety of ways that we understand the job that needs to be done. For example, we might read a design brief or have a discussion with a client or anything like that. But in the process of learning CAD and being given exercises and activities the way we're doing in this course, one of the important ways for you to understand the job that needs to be done is to be able to read and interpret correctly an engineering drawing. Usually, in this course, for the purpose of reproducing the geometry found in those engineering drawings. So, in this video, I'll take the time to describe to you part drawings and assembly drawings. And I will simply attempt to demystify what otherwise may appear like a complicated set of documents. But as soon as you sort of break them down and see what's in them, you'll be able to begin the process of reading and interpreting them correctly. So, I'm gonna jump right now into a set of graphics. We're gonna take a look at these graphics now, and we can see there is a product here. It is a turbocharger. This particular turbocharger for the discussion that we're gonna have right now has two pages of a drawing. So, the drawing is shown right here. We're gonna look at sheet 1 of this drawing set, and we're just gonna start breaking down its pieces, and then we'll look at sheet 2, and then we're gonna spend a little bit of time looking at an assembly drawing. OK. For sheet 1, we need to understand that the overall graphic that's around the edge is called the sheet format. In fact, we can just sort of take out all the geometry and specific geometric information and what's left is called the sheet format. All right. The sheet format has zone markers. These zone markers are used for to facilitate communication on design teams or across a large geographic distances. We can say, hey, something's going on in C2, area C2, of the drawing. Let's take a look and see what that is. Also, in the drawing we have the thing that is called the revision block. The revision block describes the latest change at least that has been made to the drawing. In this case, it's a revision A, meaning it's just the initial release. The revision block only appears on sheet 1. We also have the thing on the drawing that's called the title block. The title block has a lot of very important information. And within the title block, we find things that are critical for being able to reproduce the geometry that's in the drawing. And so, we're gonna take a deeper look now at the title block, and we're gonna look at three separate parts of the title block. First, we're gonna take a look at this part here, which, of course, has like the title, also has a thing called the size, and, by the way, we are looking at B size drawings. These are 11 by 17 inches. That's how big those drawings are. Now, a couple of key things to pay attention to here. Item number 1 is you should always have a sense for what revision of the drawing you're looking at. This is important because occasionally you'll be working with a colleague or another entity, maybe a supplier or something like this, and you want to make sure that you're on the same page. And the way we do that is you make sure you're looking at the same revision of the drawing. Speaking of pages, which is not what I meant just a minute ago, there are multiple sheets in this drawing set, and there's always a list of how many sheets there are. That's important to know because if there's additional information on sheet 2 or 3 or 4 or 5 or 6, we want to go and get them. Also, we have information that is related to the overall mass properties of the object represented in the drawing. In this case, the weight is shown, and then also here to pay attention to is the scale. The scale is important to understand in the sense that if the scale was 1 to 1, then the object in the drawing would be printed on the drawing at the same size as the actual object. When the scale is 1 to 5, in this case, every 1 inch that's printed on the drawing represents 5 inches in reality. All right. The next part of the title block that we're gonna take a look at captures authorship. And also, thedrawing has been checked, and frankly, you should always have your drawings checked. And you should not trust drawings that have not yet been checked. Also, in this part of the drawing, we find the units for how the drawing was created. In this case, this drawing is in the units of millimeters. We also find the important area that is describing the material of the object represented in the drawing. In this case, the turbocharger in the drawing is of titanium grade 5. Also, in the drawing, we can find finish if there is one specified and if there's not one specified, it will simply say that. And then, also, here there's a section for comments. And in this course, this is where we actually put our color specifications. This is not a color specification for the turbocharger. This would have meant the turbocharger was perfectly red. But I have just put that in there as a quick sample just to show you that those will often show up in our comments. We also then have this other part of the title block, which is the sheet tolerances. Now, what's going on with sheet tolerances? First of all, we have to know that this part represents important information relative to the dimensions in the drawing. So, we're going to go look at one of the dimensions right now. From the top edge of this object to the center of this hole is supposed to be 23.00 millimeters. Now, we can understand from this part of the drawing and from the sheet tolerances that what this means is that because our has two bits of information beyond the decimal point, then we will be referring to this portion in the general tolerances, the sheet tolerances, which mean that the 23 is plus or minus 0.15 millimeters. Now, if our drawing would have instead just had one bit of information beyond the decimal spot, we would have been looking at plus or minus 0.25 millimeters. Now, this is important because all of those tolerances are essential, but we don't want to put them, every single one of them on the drawing itself because it will clutter up the drawings. So, they go into the sheet definition, so into the sheet tolerances. That's what that means. OK. Well, those were the main things that we wanted to look at in the title block. We have finished our sort of deep dive on the title block. And then, I'll just go through a few other things here and say that drawings always have a set of general drawing notes. These drawing notes apply to the entire drawing set, sometimes just the entire page, but sometimes it can apply to all the sheets. But then we also have specific notes that can apply to just a specific part located or a specific portion of a part located on the drawing, and there's always a leader line that is connected to where that note matters. All right. Now, we have to look at the geometry of the drawing. Here, we have what's called the orthographic projections, the orthographic projection views we could call them. OK. And then, we also have within those orthographic projection views, a special kind of line that we don't see anywhere else and that is a dashed line and that dashed line is called a hidden line. And a hidden line is like an X-ray view we basically can see into the object and what all the dashed line are representing internal geometry that we can't see from outside but we can see through in an X-ray sort of form. Now, there is another image on here, another view, it's called the isometric view it's the one at the top right of the drawing, and the top right drawing view the isometric view never has hidden lines. This is a standard for drawing so we can always see the isometric view and we can have a sense for what the object is that's to help us with that, but it's not gonna show us hidden lines. Now, it's worth spending just a little bit of time trying to understand what is this orthographic projection. If you understand the thing that I'm going to describe in the next moment, then orthographic projections will become meaningful to you, will become useful, and you'll be able to understand engineering drawings of this form indefinitely into the future. So, I'm gonna show you the same orthographic projections shown in just a little bit larger here, and what we want to do is take a look at the front view for a second. When we're looking at the front view, what we are really looking at is a projection of the object directly onto its front face. Now, if you can see the red box that's on the right-hand side here, the front view is exactly the front view direction. Now, if I were to take a line and draw it on the paper between the top view and the front view and then fold it right there at 90 degrees, I would create the edge of a cube. And the edge of that cube would be such that when I look down from the top of the cube, I see the top view, and when I look at the front of the cube, I see the front view. Now, likewise, if I were to fold between the front view and the right view and leave the paper at 90 degrees, I'd form another edge of a cube. And when I look at the right side of that cube, I would see the right view, and when I look at the front view, I would see the front view, and if I look at the top view, I'd see the top view. And this is how an orthographic projection works. It's simple when someone has described it to you, but is otherwise, for some people, not super obvious. So, hopefully, you will walk away with a little bit of information there on how to interpret these orthographic projections. So, now, you should be able to look at an engineering drawing like this and not get super overwhelmed by it because you know that all the information around the edge is the sheet format. You know that down in the bottom right corner, we have our title block with a bunch of essential information. We have our revision block at the top right. Then, we have two kinds of views here. We have the orthographic projections, which have the front, right, and top view, and then we have the isometric view, which is shown without hidden lines in the top right portion of the drawing and helps us get even a better sense for what the object is all about. OK. That was what sheet 1 looked like. Now, in sheet 1, we saw those orthographic projections; we saw the isometric view. And in sheet 2, we see what is called auxiliary views. Now, auxiliary views are not limited to being on page 2, they could be on page 1. But in this case, in this particular drawing, our auxiliary views happen to be on sheet 2. They could have been on sheet 3, 4, 5, 6, or 1. OK. Now in order to understand the auxiliary views, we need to zoom in just a bit on this portion of sheet 1 and see what's going on here. Within this set portion, when we're looking at the front view from sheet 1, we see this dashed line with the two arrows on it. This is called a section marker, and what a section marker means is that we are going to slice the part right where the dashed line is, and then we're going to look in the directions of the arrows labeled AA. And what are we gonna see if we do that? We're gonna see this box that's now highlighted on sheet 2. How do we know that that's the box we're gonna see? Well, primarily, we know it's the box we're gonna see because it's labeled. It's called section AA, and that's exactly what we were looking at in sheet 1 was a marker showing what section AA would be. And now on sheet 2, we're looking at that. So, we're going to go take a look even deeper now at sheet 2. Now that we know that we're looking at 2 section views, section views are auxiliary views. Alright, now a few things to point out on this sheet. We have the name of the auxiliary view with its scale, if it has been scaled, and this one has been scaled. We also see that there's a new kind of line that's appearing on the drawing, and this is the crosshatch. Whenever there's a crosshatch, this means that we have sliced through material and we're actually looking at material and not void space. So, for example, if we look at the holes that are on the same view, those holes are not crosshatched, that means they're void space. It means there's nothing there, but the crosshatch means there is something there and that's material. All right. What is the next piece we're gonna look at? We're gonna notice here that there are center lines and center marks. These pieces of sort of invisible geometry, maybe we can call them, are important for dimensioning too or understanding symmetries in some cases. All right. We also have in this sheet 2 dimensions, such as this dimension, which means that the overall length of this object is 268 millimeters. We also see some other dimensions, some that appear a little bit more complicated. And what this dimension means, the dimension that says 4X R20.00 means that there are four arcs on this part that have a radius of 20 millimeters. And then, likewise, there is a dimension here that says there are four circles on this part that have a diameter of 20 millimeters. So, when there's an R, this is a dimension that goes on an arc or an incomplete circle when there is the diameter symbol or the letters DIA. This means that this is a diameter and we do that for full circles. The 4X that precedes it in this case simply means that there are four identical geometries on this part that have that same dimension. Now, of course, on this drawing, there are many dimensions. That is the purpose of the drawing is actually to convey geometric information. And don't forget the rectangular red box there in the title block the drawing is also designed to convey material information. All right. So, we have just taken a look at part drawings. In this case, a multi-sheet part drawing for this turbocharger. And hopefully, we have, as I mentioned before, demystified it a little bit and shown that it is full of orthographic projection views, isometric views, and some auxiliary views, and then those allow dimensions to be put onto the object that help us understand more and more about it. OK. It is now time for us to stop thinking about part drawings, and we're going to talk about assembly drawings. And in this case, I'm showing you a five sheet assembly drawing for the NES game controller by Nintendo. Now, it's five sheets because we need to know this thing in the top left corner is just an isometric screenshot just to let you know the object that we're working on. It's not part of the actual drawing set. All right, so within this drawing set, however, there are five sheets. And we're going to take a look at just three of those sheets— sheet 1, sheet 2, and sheet 3. The other sheets are valuable, but they're not going to teach us anything new about how to interpret an assembly drawing, which is what we're gonna do right now. All right, take a look at this first sheet of the Nintendo NES game controller, and let's notice first of all the things that are similar from the part drawing, part drawings that we looked at. Sheet formats the same exact concept; zone marker, same concept; revision block, the same; title block, same concept; general notes, same concept. We have orthographic projection views here. We also have isometric views, and we also have dimensions. So, what's new then? Well, there are some new things here. We have assembly dimensions. These are dimensions that don't exist on any part drawing. This is one of the main purposes of assembly drawings is to help convey dimensions that are essential, but don't exist on part drawings. For example, this is measuring from one edge of a part to another edge of another part. That 17.20. All right. We also can notice here in the title block that material and finish don't make a lot of sense in an assembly drawing because the assembly is made up of various parts that all have potentially different materials and different finishes. And therefore, it is traditional and expected that those bits of information don't exist on the assembly drawing, but that the reader of the assembly drawing is encouraged or directed to the actual art drawings. All right, let's take a look at, oh, that's the part that I just talked about right now. OK. Now on to sheet 2. All right. For sheet 2, it's essential to realize that there is a new kind of auxiliary view that we're looking at now and it's called an exploded view. And the beauty of the exploded view is that it's broken up the part into all of its pieces so we can take a deeper look at them. Now, each of the parts has a callout balloon on it. And the callout balloon has a corresponding line in this table which is called the bill of materials or sometimes called the part list, but we will call it the bill of materials. Now, all of the objects in this particular assembly have a callout balloon and have a location in the bill of materials. Also, in the assembly drawing, we can notice the thing that's called the explode line. The explode line helps to understand that, for example, the bottom left the screw goes through that bottom cover through the circuit board through the membrane and up into the top cover, and it is an indication of how these parts line up with each other. OK. We're now going to take a look at step, excuse me, sheet 3. And in sheet 3, we're going to see that a number of things are the same as they were in part drawings. For example, the section markers, the section views, the general nodes, the specific notes. But we now have a new thing that could have existed in a part drawing but it didn't exist in our part drawing for the turbocharger. It exists in this one, so I thought I'd take a second to talk about it and that is called the detail view. And a detail view is another auxiliary view and what it is is it's a zoomed in portion of the stuff that's inside the detail view marker. The detail view marker is that circular line that has two arrows on it pointing to a D, in this case, and that line is dashed. And that tells us that we're gonna zoom in on that area, and it's going to appear somewhere else on the drawing, and it's going to tell us something that is otherwise hard to look at at the size that it exists normally in the drawing. OK. So, that's what you need to know about assembly drawings and what you need to know about part drawings. So, before we leave this whole topic, I think it's worth saying a few things. And item number 1 here is I hope that when you look at the engineering drawings, they won't look as daunting as they did before we had this small discussion. But what I hope mostly is that you'll actually look at the engineering drawings. You need to spend some time with the engineering drawings. OK. I want to spend 5 to 10 minutes with each of the drawings. OK. We want to examine each engineering drawing starting with the title block, then with the notes on page one. Then, we want to look at the views, try to understand what the views can tell us and why they're there. We want to try to envision the geometry. We want to do the same then for all those pages. And we wanna look for details such as specific dimensions or specific details that maybe in a detail view or in a section view. OK. Just as a final recap on here, we're after getting good at CAD fluency. CAD fluency starts by having a good understanding of why you need to create a model. That model understanding can come from a variety of places, including talking to a client or following a product development process for a given company. In this case, in this course, we're gonna have a number of exercises at the beginning here where you create geometry that's conveyed to you in an engineering drawing. So, you need to learn how to read those engineering drawings. And this video demystified them just a little bit hopefully making them less daunting, something you're willing to engage with and to actually read.