0:00:00.200,0:00:02.200
As you work to develop CAD fluency,

0:00:02.279,0:00:05.550
which means to be able to do your CAD work quickly and accurately,

0:00:05.800,0:00:08.949
it helps to have a good CAD process.

0:00:09.210,0:00:13.189
Now, a good CAD process always starts with understanding

0:00:13.470,0:00:15.229
the purpose for the CAD work.

0:00:15.399,0:00:15.920
In other words,

0:00:16.350,0:00:18.309
understanding the job that needs to be done.

0:00:18.600,0:00:20.350
Now in the product development process,

0:00:20.639,0:00:24.200
we have a variety of ways that we understand the job that needs to be done.

0:00:24.319,0:00:24.750
For example,

0:00:24.799,0:00:25.200
we might

0:00:25.649,0:00:25.850
read

0:00:25.889,0:00:30.319
a design brief or have a discussion with a client or anything like that.

0:00:30.690,0:00:36.529
But in the process of learning CAD and being given exercises and

0:00:36.849,0:00:39.319
activities the way we're doing in this course,

0:00:39.729,0:00:43.500
one of the important ways for you to understand the job that needs to be done

0:00:43.889,0:00:44.439
is

0:00:44.689,0:00:46.279
to be able to read

0:00:46.569,0:00:49.529
and interpret correctly an engineering drawing.

0:00:50.150,0:00:50.950
Usually,

0:00:51.270,0:00:54.619
in this course, for the purpose of reproducing the geometry

0:00:55.029,0:00:55.540
found

0:00:55.790,0:00:57.459
in those engineering drawings.

0:00:57.590,0:00:58.659
So, in this video,

0:00:58.909,0:01:02.779
I'll take the time to describe to you part drawings

0:01:03.060,0:01:04.430
and assembly drawings.

0:01:04.529,0:01:05.800
And I will simply

0:01:06.349,0:01:06.849
attempt

0:01:07.110,0:01:10.339
to demystify what otherwise may appear

0:01:10.669,0:01:13.019
like a complicated set of documents.

0:01:13.110,0:01:16.110
But as soon as you sort of break them down and see what's in them,

0:01:16.470,0:01:21.540
you'll be able to begin the process of reading and interpreting them correctly.

0:01:21.750,0:01:24.349
So, I'm gonna jump right now into a set of graphics.

0:01:24.430,0:01:27.269
We're gonna take a look at these graphics now, and we can see

0:01:28.410,0:01:29.309
there is a product here.

0:01:29.370,0:01:30.760
It is a turbocharger.

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This particular turbocharger for the discussion

0:01:34.010,0:01:38.059
that we're gonna have right now has two pages

0:01:38.290,0:01:39.000
of a drawing.

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So, the drawing is shown right here.

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We're gonna look at sheet 1

0:01:43.089,0:01:44.319
of this drawing set,

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and we're just gonna start

0:01:46.330,0:01:48.440
breaking down its pieces,

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and then we'll look at sheet 2, and then we're gonna

0:01:51.209,0:01:54.610
spend a little bit of time looking at an assembly drawing.

0:01:55.339,0:01:55.349
OK.

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For sheet 1,

0:01:57.769,0:02:01.809
we need to understand that the overall graphic that's

0:02:01.809,0:02:04.120
around the edge is called the sheet format.

0:02:04.330,0:02:04.680
In fact,

0:02:04.730,0:02:05.180
we can

0:02:05.370,0:02:08.440
just sort of take out all the geometry and specific

0:02:08.809,0:02:12.809
geometric information and what's left is called the sheet format.

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All right.

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The sheet format has zone markers.

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These zone markers are used for to facilitate communication

0:02:20.550,0:02:24.220
on design teams or across a large geographic distances.

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We can say,

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hey,

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something's going on in C2, area C2, of the drawing.

0:02:29.110,0:02:30.940
Let's take a look and see what that is.

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Also, in

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the

0:02:35.630,0:02:38.539
drawing we have the thing that is called the revision block.

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The revision block describes the latest change at

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least that has been made to the drawing.

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In this case,

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it's a revision A,

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meaning it's just the initial release.

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The revision block only appears on sheet 1.

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We also have the thing on the drawing that's called the title block.

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The title block

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has a lot of very important information.

0:02:59.630,0:03:02.020
And within the title block, we find things that

0:03:02.020,0:03:05.250
are critical for being able to reproduce the geometry

0:03:05.619,0:03:06.479
that's in

0:03:06.940,0:03:10.149
the drawing. And so, we're gonna take a deeper look now at the title block,

0:03:10.419,0:03:13.380
and we're gonna look at three separate parts of the title block.

0:03:13.500,0:03:17.649
First, we're gonna take a look at this part here, which, of course, has like the title,

0:03:17.940,0:03:19.610
also has a thing called

0:03:19.850,0:03:23.979
the size, and, by the way, we are looking at B size drawings.

0:03:24.020,0:03:26.490
These are 11 by 17

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inches.

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That's how big those drawings are.

0:03:30.149,0:03:32.759
Now, a couple of key things to pay attention to here.

0:03:33.080,0:03:35.830
Item number 1 is you should always have a sense

0:03:35.830,0:03:38.699
for what revision of the drawing you're looking at.

0:03:38.990,0:03:40.990
This is important because occasionally you'll

0:03:40.990,0:03:43.179
be working with a colleague or another

0:03:43.589,0:03:44.990
entity,

0:03:45.130,0:03:47.259
maybe a supplier or something like this,

0:03:47.470,0:03:50.309
and you want to make sure that you're on the same page. And the

0:03:50.309,0:03:53.300
way we do that is you make sure you're looking at the same revision

0:03:53.589,0:03:54.350
of the drawing.

0:03:54.899,0:03:56.039
Speaking of pages,

0:03:56.380,0:03:58.130
which is not what I meant just a minute ago,

0:03:58.419,0:03:59.369
there

0:03:59.539,0:04:00.130
are

0:04:00.380,0:04:02.330
multiple sheets in this drawing set,

0:04:02.380,0:04:04.740
and there's always a list of how many sheets there are.

0:04:04.820,0:04:07.660
That's important to know because if there's additional information on

0:04:07.660,0:04:10.220
sheet 2 or 3 or 4 or 5 or 6,

0:04:10.259,0:04:11.889
we want to go and get them.

0:04:12.539,0:04:13.770
Also, we have

0:04:14.389,0:04:16.209
information that is

0:04:16.399,0:04:18.329
related to the overall

0:04:19.390,0:04:24.170
mass properties of the object represented in the drawing. In this case, the weight

0:04:24.540,0:04:29.010
is shown, and then also here to pay attention to is the scale.

0:04:29.260,0:04:33.929
The scale is important to understand in the sense that if the scale was 1 to 1,

0:04:34.260,0:04:38.450
then the object in the drawing would be printed

0:04:38.700,0:04:41.820
on the drawing at the same size as the actual object.

0:04:42.279,0:04:43.790
When the scale is 1 to 5,

0:04:43.920,0:04:44.429
in this case,

0:04:44.480,0:04:48.119
every 1 inch that's printed on the drawing represents 5 inches

0:04:48.519,0:04:48.910
in

0:04:49.119,0:04:49.989
reality.

0:04:50.279,0:04:50.429
All right.

0:04:50.440,0:04:54.399
The next part of the title block that we're gonna take a look at captures authorship.

0:04:54.679,0:04:58.429
And also, thedrawing has been checked, and frankly, you should

0:04:58.920,0:05:01.239
always have your drawings checked. And you should not

0:05:01.239,0:05:03.359
trust drawings that have not yet been checked.

0:05:04.000,0:05:07.029
Also, in this part of the drawing, we find the units

0:05:07.359,0:05:07.950
for

0:05:08.209,0:05:09.799
how the drawing was created.

0:05:09.839,0:05:12.880
In this case, this drawing is in the units of millimeters.

0:05:13.480,0:05:15.149
We also find the important

0:05:15.649,0:05:21.200
area that is describing the material of the object represented in the drawing.

0:05:21.209,0:05:21.869
In this case,

0:05:22.010,0:05:25.399
the turbocharger in the drawing is of titanium grade 5.

0:05:25.970,0:05:28.329
Also, in the drawing, we can find

0:05:28.540,0:05:30.579
finish if there is one specified and if there's

0:05:30.579,0:05:32.450
not one specified, it will simply say that.

0:05:32.459,0:05:32.940
And then,

0:05:33.220,0:05:36.049
also, here there's a section for comments. And in this course,

0:05:36.339,0:05:39.109
this is where we actually put our color specifications.

0:05:39.649,0:05:39.709
This

0:05:39.739,0:05:43.019
is not a color specification for the turbocharger.

0:05:43.059,0:05:44.769
This would have meant the turbocharger was

0:05:45.220,0:05:46.459
perfectly red.

0:05:47.010,0:05:47.380
But

0:05:47.450,0:05:50.010
I have just put that in there as a quick sample just

0:05:50.010,0:05:53.920
to show you that those will often show up in our comments.

0:05:54.089,0:05:56.769
We also then have this other part of the title block,

0:05:57.089,0:05:59.420
which is the sheet tolerances.

0:05:59.579,0:06:01.450
Now, what's going on with sheet tolerances?

0:06:01.529,0:06:01.820
First of all,

0:06:01.850,0:06:03.839
we have to know that this part represents

0:06:04.209,0:06:07.809
important information relative to the dimensions in the drawing.

0:06:08.850,0:06:10.929
So, we're going to go look at one of the dimensions right now.

0:06:11.000,0:06:11.549
From the

0:06:11.799,0:06:14.829
top edge of this object to the center of this hole

0:06:15.119,0:06:19.079
is supposed to be 23.00 millimeters.

0:06:19.679,0:06:24.790
Now, we can understand from this part of the drawing and from the sheet tolerances

0:06:25.109,0:06:26.429
that what this means

0:06:26.799,0:06:28.010
is that because our

0:06:28.625,0:06:29.494
has two

0:06:32.144,0:06:34.494
bits of information beyond the decimal point,

0:06:34.785,0:06:36.575
then we will be referring to

0:06:36.904,0:06:39.135
this portion in the general

0:06:39.785,0:06:40.464
tolerances,

0:06:40.505,0:06:41.695
the sheet tolerances,

0:06:41.984,0:06:44.355
which mean that the 23

0:06:44.665,0:06:47.475
is plus or minus 0.15 millimeters.

0:06:48.184,0:06:48.575
Now,

0:06:48.864,0:06:51.945
if our drawing would have instead just had one

0:06:52.329,0:06:55.190
bit of information beyond the decimal spot,

0:06:55.359,0:06:59.170
we would have been looking at plus or minus 0.25 millimeters.

0:06:59.559,0:07:03.070
Now, this is important because all of those tolerances are essential,

0:07:03.359,0:07:04.579
but we don't want to put them,

0:07:04.720,0:07:07.350
every single one of them on the drawing itself

0:07:07.880,0:07:09.029
because it will

0:07:09.609,0:07:10.649
clutter up the drawings.

0:07:10.679,0:07:12.200
So, they go into the sheet

0:07:12.750,0:07:15.320
definition, so into the sheet tolerances.

0:07:15.630,0:07:17.309
That's what that means.

0:07:17.429,0:07:17.859
OK.

0:07:18.029,0:07:21.190
Well, those were the main things that we wanted to look at in the

0:07:21.190,0:07:24.959
title block. We have finished our sort of deep dive on the title block.

0:07:25.230,0:07:28.670
And then, I'll just go through a few other things here and say that

0:07:29.029,0:07:31.019
drawings always have

0:07:31.309,0:07:33.390
a set of general drawing notes.

0:07:33.429,0:07:36.549
These drawing notes apply to the entire drawing

0:07:37.010,0:07:37.410
set,

0:07:37.779,0:07:39.299
sometimes just the entire page,

0:07:39.350,0:07:42.279
but sometimes it can apply to all the sheets.

0:07:42.450,0:07:46.440
But then we also have specific notes that can apply to just a specific

0:07:46.809,0:07:51.100
part located or a specific portion of a part located on the drawing,

0:07:51.130,0:07:52.760
and there's always a leader line

0:07:53.010,0:07:55.730
that is connected to where that note matters.

0:07:56.529,0:07:56.549
All right.

0:07:57.519,0:07:59.739
Now, we have to look at the geometry

0:08:00.040,0:08:05.190
of the drawing. Here, we have what's called the orthographic projections,

0:08:05.399,0:08:08.119
the orthographic projection views we could call them.

0:08:08.200,0:08:08.670
OK.

0:08:08.880,0:08:09.390
And then,

0:08:09.519,0:08:10.869
we also have

0:08:11.279,0:08:15.839
within those orthographic projection views, a special kind of line that we don't

0:08:15.839,0:08:19.480
see anywhere else and that is a dashed line and that dashed line

0:08:19.614,0:08:22.084
is called a hidden line. And a hidden line is

0:08:22.084,0:08:25.394
like an X-ray view we basically can see into the object

0:08:25.725,0:08:27.725
and what all the dashed line

0:08:27.725,0:08:30.994
are representing internal geometry

0:08:31.244,0:08:33.275
that we can't see from outside but we

0:08:33.604,0:08:36.354
can see through in an X-ray sort of form.

0:08:36.683,0:08:38.715
Now, there is another image

0:08:39.005,0:08:42.525
on here, another view, it's called the isometric view it's the one at the top

0:08:43.169,0:08:46.440
right of the drawing, and the top right drawing

0:08:46.710,0:08:50.320
view the isometric view never has hidden lines.

0:08:50.539,0:08:50.780
This

0:08:50.789,0:08:55.380
is a standard for drawing so we can always see the isometric view

0:08:55.590,0:08:59.229
and we can have a sense for what the object is that's to help us with that,

0:08:59.309,0:09:01.830
but it's not gonna show us hidden lines.

0:09:01.950,0:09:02.989
Now, it's worth spending

0:09:03.565,0:09:03.924
just

0:09:03.934,0:09:06.005
a little bit of time trying

0:09:06.005,0:09:09.405
to understand what is this orthographic projection.

0:09:09.645,0:09:12.994
If you understand the thing that I'm going to describe in the next moment,

0:09:13.244,0:09:16.395
then orthographic projections will become meaningful to you,

0:09:16.604,0:09:17.364
will become useful,

0:09:17.375,0:09:19.734
and you'll be able to understand engineering drawings

0:09:20.085,0:09:20.474
of

0:09:20.565,0:09:23.354
this form indefinitely into the future.

0:09:23.575,0:09:26.794
So, I'm gonna show you the same orthographic projections

0:09:27.205,0:09:27.965
shown

0:09:28.700,0:09:31.080
in just a little bit larger here,

0:09:31.369,0:09:34.799
and what we want to do is take a look at the front view for a second.

0:09:35.010,0:09:36.700
When we're looking at the front view,

0:09:37.090,0:09:37.440
what

0:09:37.489,0:09:39.159
we are really looking at

0:09:39.500,0:09:40.359
is

0:09:40.369,0:09:41.000
a

0:09:41.369,0:09:42.880
projection

0:09:43.409,0:09:46.919
of the object directly onto its front face.

0:09:47.289,0:09:47.719
Now,

0:09:48.169,0:09:52.640
if you can see the red box that's on the right-hand side here,

0:09:53.130,0:09:55.929
the front view is exactly the front view direction.

0:09:56.780,0:09:56.969
Now,

0:09:57.000,0:09:58.030
if I were to

0:09:58.520,0:10:00.320
take a line

0:10:00.960,0:10:04.770
and draw it on the paper between the top view and the front view

0:10:05.119,0:10:08.510
and then fold it right there at 90 degrees,

0:10:08.719,0:10:10.390
I would create the edge of a cube.

0:10:11.020,0:10:13.210
And the edge of that cube would be such that when I

0:10:13.210,0:10:16.359
look down from the top of the cube, I see the top view,

0:10:16.650,0:10:19.260
and when I look at the front of the cube, I see the front view.

0:10:19.530,0:10:20.250
Now, likewise,

0:10:20.369,0:10:23.090
if I were to fold between the front view and

0:10:23.090,0:10:25.789
the right view and leave the paper at 90 degrees,

0:10:25.809,0:10:27.200
I'd form another

0:10:27.570,0:10:28.849
edge of a cube.

0:10:29.590,0:10:32.099
And when I look at the right side of that cube, I would

0:10:32.099,0:10:34.299
see the right view, and when I look at the front view,

0:10:34.419,0:10:36.380
I would see the front view, and if I look at the top view,

0:10:36.460,0:10:37.549
I'd see the top view.

0:10:37.739,0:10:41.679
And this is how an orthographic projection works.

0:10:41.820,0:10:42.969
It's simple

0:10:43.739,0:10:45.280
when someone has described it to you,

0:10:45.349,0:10:46.570
but is otherwise,

0:10:48.109,0:10:48.789
for some people,

0:10:48.830,0:10:51.270
not super obvious. So, hopefully, you will walk

0:10:51.270,0:10:53.330
away with a little bit of information there

0:10:53.590,0:10:54.940
on how to interpret

0:10:55.229,0:10:55.700
these

0:10:55.989,0:10:57.820
orthographic projections.

0:10:58.109,0:11:01.859
So, now, you should be able to look at an engineering drawing like this

0:11:02.150,0:11:04.789
and not get super overwhelmed by it because

0:11:04.789,0:11:06.979
you know that all the information around the edge

0:11:07.429,0:11:08.809
is the sheet format.

0:11:09.030,0:11:11.390
You know that down in the bottom right corner, we

0:11:11.390,0:11:14.299
have our title block with a bunch of essential information.

0:11:14.510,0:11:16.429
We have our revision block at the top right.

0:11:16.880,0:11:19.080
Then, we have two kinds of views here.

0:11:19.159,0:11:22.400
We have the orthographic projections, which have the front,

0:11:22.599,0:11:22.789
right,

0:11:22.799,0:11:25.669
and top view, and then we have the isometric view,

0:11:26.000,0:11:30.869
which is shown without hidden lines in the top right portion of the drawing

0:11:31.080,0:11:32.289
and helps us get

0:11:32.440,0:11:35.250
even a better sense for what the object is all about.

0:11:36.289,0:11:36.869
OK.

0:11:37.169,0:11:39.159
That was what sheet 1 looked like.

0:11:39.530,0:11:40.000
Now,

0:11:40.270,0:11:41.130
in sheet 1,

0:11:41.229,0:11:43.119
we saw those orthographic projections;

0:11:43.210,0:11:45.080
we saw the isometric view.

0:11:46.159,0:11:47.880
And in sheet 2,

0:11:48.039,0:11:50.039
we see what is called auxiliary views.

0:11:50.119,0:11:50.239
Now,

0:11:50.250,0:11:52.270
auxiliary views are not limited to

0:11:52.599,0:11:53.640
being on page 2,

0:11:53.719,0:11:55.119
they could be on page 1.

0:11:55.830,0:11:57.080
But in this case,

0:11:57.320,0:11:58.669
in this particular drawing,

0:11:58.960,0:12:01.789
our auxiliary views happen to be on sheet 2.

0:12:02.000,0:12:04.510
They could have been on sheet 3, 4, 5, 6,

0:12:04.679,0:12:05.309
or 1.

0:12:05.559,0:12:06.000
OK.

0:12:06.780,0:12:08.700
Now in order to understand the auxiliary views,

0:12:08.780,0:12:09.520
we need to

0:12:09.859,0:12:11.210
zoom in just a bit

0:12:11.500,0:12:13.659
on this portion of sheet 1

0:12:14.059,0:12:15.700
and see what's going on here.

0:12:16.020,0:12:18.210
Within this set portion,

0:12:18.380,0:12:20.770
when we're looking at the front view from sheet 1,

0:12:21.020,0:12:24.289
we see this dashed line with the two arrows on it.

0:12:24.609,0:12:26.530
This is called a section marker,

0:12:26.700,0:12:30.530
and what a section marker means is that we are going to slice the part

0:12:30.830,0:12:32.739
right where the dashed line is, and then we're going

0:12:32.739,0:12:36.460
to look in the directions of the arrows labeled AA.

0:12:36.750,0:12:38.340
And what are we gonna see if we do that?

0:12:38.380,0:12:39.250
We're gonna see

0:12:39.460,0:12:40.809
this box that's now

0:12:41.099,0:12:42.739
highlighted on sheet 2.

0:12:43.059,0:12:45.010
How do we know that that's the box we're gonna see?

0:12:45.140,0:12:45.260
Well,

0:12:45.390,0:12:47.770
primarily, we know it's the box we're gonna see because

0:12:47.969,0:12:48.809
it's labeled.

0:12:49.020,0:12:53.179
It's called section AA, and that's exactly what we were looking at

0:12:53.179,0:12:57.820
in sheet 1 was a marker showing what section AA would be.

0:12:58.140,0:12:59.239
And now on sheet 2,

0:12:59.280,0:12:59.880
we're looking at that.

0:12:59.960,0:13:00.609
So, we're going to

0:13:00.840,0:13:03.510
go take a look even deeper now at sheet 2.

0:13:03.760,0:13:05.640
Now that we know that we're looking at 2

0:13:06.030,0:13:07.159
section views,

0:13:07.280,0:13:09.280
section views are auxiliary views.

0:13:10.080,0:13:10.400
Alright,

0:13:10.520,0:13:12.669
now a few things to point out on this sheet.

0:13:13.000,0:13:13.669
We have

0:13:14.229,0:13:17.229
the name of the auxiliary view with its scale,

0:13:17.400,0:13:19.869
if it has been scaled, and this one has been scaled.

0:13:20.710,0:13:21.869
We also see that

0:13:22.109,0:13:25.049
there's a new kind of line that's appearing on the drawing,

0:13:25.070,0:13:26.460
and this is the crosshatch.

0:13:26.669,0:13:27.909
Whenever there's a crosshatch,

0:13:27.989,0:13:30.419
this means that we have sliced through material

0:13:30.630,0:13:33.979
and we're actually looking at material and not void space.

0:13:34.229,0:13:34.859
So, for example,

0:13:34.909,0:13:37.739
if we look at the holes that are on the same view,

0:13:38.030,0:13:39.950
those holes are not crosshatched, that means

0:13:39.950,0:13:42.299
they're void space. It means there's nothing there,

0:13:42.590,0:13:46.309
but the crosshatch means there is something there and that's material.

0:13:46.830,0:13:47.070
All right.

0:13:47.190,0:13:48.820
What is the next piece we're gonna look at?

0:13:48.950,0:13:53.059
We're gonna notice here that there are center lines and center marks.

0:13:53.429,0:13:54.859
These pieces of

0:13:55.929,0:13:57.809
sort of invisible geometry,

0:13:57.869,0:13:59.059
maybe we can call them,

0:13:59.309,0:14:01.750
are important for dimensioning too

0:14:02.330,0:14:05.349
or understanding symmetries in some cases.

0:14:05.809,0:14:06.049
All right.

0:14:06.169,0:14:09.679
We also have in this sheet 2 dimensions,

0:14:10.000,0:14:10.969
such as this dimension,

0:14:11.010,0:14:16.210
which means that the overall length of this object is 268 millimeters.

0:14:16.729,0:14:18.770
We also see some other dimensions,

0:14:18.929,0:14:21.520
some that appear a little bit more complicated.

0:14:21.770,0:14:23.590
And what this dimension means,

0:14:24.010,0:14:25.239
the dimension that says

0:14:25.570,0:14:28.960
4X R20.00

0:14:29.369,0:14:29.859
means

0:14:30.130,0:14:33.890
that there are four arcs on this part that have a radius

0:14:34.369,0:14:35.419
of 20 millimeters.

0:14:36.010,0:14:37.520
And then, likewise,

0:14:37.849,0:14:39.700
there is a dimension here that says

0:14:40.049,0:14:44.080
there are four circles on this part that have a diameter

0:14:44.369,0:14:46.630
of 20 millimeters. So, when there's an R,

0:14:47.010,0:14:49.039
this is a dimension that goes on an arc

0:14:49.409,0:14:55.090
or an incomplete circle when there is the diameter symbol or the letters DIA.

0:14:55.640,0:14:59.989
This means that this is a diameter and we do that for full circles.

0:15:00.200,0:15:03.549
The 4X that precedes it in this case simply means that

0:15:03.799,0:15:04.750
there are four

0:15:04.919,0:15:07.669
identical geometries on this part

0:15:07.919,0:15:09.190
that have that same

0:15:09.440,0:15:10.049
dimension.

0:15:11.099,0:15:14.940
Now, of course, on this drawing, there are many dimensions. That is the purpose

0:15:15.190,0:15:19.580
of the drawing is actually to convey geometric information.

0:15:19.989,0:15:24.080
And don't forget the rectangular red box there in the title block

0:15:24.270,0:15:26.520
the drawing is also designed to convey

0:15:27.109,0:15:28.190
material information.

0:15:28.679,0:15:28.919
All right.

0:15:29.080,0:15:30.880
So, we have just taken a look at

0:15:31.289,0:15:32.080
part drawings.

0:15:32.119,0:15:32.630
In this case,

0:15:32.679,0:15:35.409
a multi-sheet part drawing for this turbocharger.

0:15:35.719,0:15:36.590
And hopefully,

0:15:36.840,0:15:37.320
we have,

0:15:37.440,0:15:38.400
as I mentioned before,

0:15:38.599,0:15:40.229
demystified it a little bit

0:15:40.479,0:15:41.450
and shown

0:15:41.840,0:15:43.599
that it is full of

0:15:44.609,0:15:46.640
orthographic projection views,

0:15:47.000,0:15:48.450
isometric views,

0:15:48.679,0:15:50.229
and some auxiliary views,

0:15:50.520,0:15:54.510
and then those allow dimensions to be put onto

0:15:54.869,0:15:58.239
the object that help us understand more and more about it.

0:15:58.700,0:15:59.380
OK.

0:15:59.549,0:16:03.020
It is now time for us to stop thinking about part drawings,

0:16:03.030,0:16:04.190
and we're going to talk about

0:16:04.469,0:16:08.390
assembly drawings. And in this case, I'm showing you a five

0:16:08.390,0:16:12.789
sheet assembly drawing for the NES game controller by Nintendo.

0:16:13.190,0:16:16.020
Now, it's five sheets because we need to know

0:16:16.469,0:16:18.619
this thing in the top left corner

0:16:18.909,0:16:20.820
is just an isometric

0:16:21.409,0:16:22.520
screenshot

0:16:22.869,0:16:25.020
just to let you know the object that we're working on.

0:16:25.070,0:16:27.590
It's not part of the actual drawing set.

0:16:28.109,0:16:28.349
All right,

0:16:28.510,0:16:29.830
so within this drawing set,

0:16:29.919,0:16:30.469
however,

0:16:31.690,0:16:36.090
there are five sheets. And we're going to take a look at just three of those sheets—

0:16:36.239,0:16:36.760
sheet 1,

0:16:37.000,0:16:37.559
sheet 2,

0:16:37.599,0:16:38.469
and sheet 3.

0:16:38.640,0:16:39.830
The other sheets are valuable,

0:16:39.960,0:16:42.799
but they're not going to teach us anything new about how to interpret

0:16:43.650,0:16:44.739
an assembly drawing,

0:16:44.789,0:16:46.460
which is what we're gonna do right now.

0:16:46.799,0:16:47.260
All right,

0:16:47.549,0:16:49.869
take a look at this first sheet

0:16:50.150,0:16:50.820
of the

0:16:51.030,0:16:54.940
Nintendo NES game controller, and let's notice first of all

0:16:55.270,0:16:57.710
the things that are similar from the part drawing,

0:16:58.570,0:16:59.969
part drawings that we looked at.

0:17:00.320,0:17:03.450
Sheet formats the same exact concept; zone marker,

0:17:03.609,0:17:07.930
same concept; revision block, the same; title block, same concept;

0:17:07.930,0:17:12.640
general notes, same concept. We have orthographic projection views here.

0:17:13.089,0:17:16.848
We also have isometric views, and we also have dimensions.

0:17:17.010,0:17:18.290
So, what's new then?

0:17:18.479,0:17:18.709
Well,

0:17:18.930,0:17:20.358
there are some new things here.

0:17:20.810,0:17:22.680
We have assembly dimensions.

0:17:22.890,0:17:25.810
These are dimensions that don't exist on any part drawing.

0:17:26.208,0:17:30.529
This is one of the main purposes of assembly drawings is to help convey

0:17:30.889,0:17:32.519
dimensions that are essential,

0:17:32.848,0:17:34.649
but don't exist on part drawings.

0:17:34.729,0:17:35.438
For example,

0:17:35.808,0:17:36.598
this is

0:17:37.078,0:17:38.918
measuring from one edge

0:17:39.660,0:17:42.579
of a part to another edge of another part.

0:17:43.369,0:17:45.369
That 17.20.

0:17:45.920,0:17:46.079
All right.

0:17:46.119,0:17:49.890
We also can notice here in the title block

0:17:50.199,0:17:52.150
that material and finish

0:17:52.520,0:17:54.630
don't make a lot of sense

0:17:54.920,0:17:57.359
in an assembly drawing because the assembly is

0:17:57.359,0:18:00.599
made up of various parts that all have potentially

0:18:00.880,0:18:03.030
different materials and different finishes.

0:18:03.359,0:18:05.510
And therefore, it is traditional

0:18:05.839,0:18:06.949
and expected

0:18:07.160,0:18:09.000
that those bits of information

0:18:09.380,0:18:11.099
don't exist on the assembly drawing,

0:18:11.140,0:18:13.500
but that the reader of the assembly drawing is

0:18:14.750,0:18:16.680
encouraged or directed

0:18:16.949,0:18:19.089
to the actual art drawings.

0:18:19.390,0:18:19.670
All right,

0:18:19.790,0:18:20.310
let's

0:18:20.709,0:18:21.410
take

0:18:22.209,0:18:23.449
a look at,

0:18:23.729,0:18:23.800
oh,

0:18:23.930,0:18:26.439
that's the part that I just talked about right now.

0:18:27.439,0:18:28.060
OK.

0:18:28.500,0:18:30.209
Now on to sheet 2.

0:18:30.459,0:18:30.739
All right.

0:18:30.939,0:18:31.969
For sheet 2,

0:18:32.020,0:18:36.020
it's essential to realize that there is a new kind of auxiliary

0:18:36.020,0:18:39.010
view that we're looking at now and it's called an exploded view.

0:18:39.420,0:18:41.180
And the beauty of the exploded view

0:18:42.410,0:18:45.319
is that it's broken up the part into all of its

0:18:45.319,0:18:47.550
pieces so we can take a deeper look at them.

0:18:47.920,0:18:48.170
Now,

0:18:48.199,0:18:50.760
each of the parts has a callout balloon on it.

0:18:51.030,0:18:55.739
And the callout balloon has a corresponding line in this table which

0:18:55.739,0:18:59.489
is called the bill of materials or sometimes called the part list,

0:18:59.500,0:19:01.500
but we will call it the bill of materials.

0:19:01.619,0:19:03.439
Now, all of the objects

0:19:03.819,0:19:04.770
in

0:19:05.099,0:19:06.689
this particular assembly

0:19:06.939,0:19:11.369
have a callout balloon and have a location in the bill of materials.

0:19:11.500,0:19:15.660
Also, in the assembly drawing, we can notice the thing that's called the explode line.

0:19:15.959,0:19:19.469
The explode line helps to understand that, for example,

0:19:19.469,0:19:23.510
the bottom left the screw goes through that bottom cover

0:19:23.959,0:19:25.229
through the circuit board

0:19:25.640,0:19:26.109
through

0:19:26.359,0:19:29.579
the membrane and up into the top cover,

0:19:29.839,0:19:31.550
and it is an indication

0:19:31.800,0:19:32.949
of how these

0:19:33.280,0:19:35.390
parts line up with each other.

0:19:35.760,0:19:35.959
OK.

0:19:36.010,0:19:38.199
We're now going to take a look at step, excuse me,

0:19:38.349,0:19:39.160
sheet 3.

0:19:39.459,0:19:40.750
And in sheet 3,

0:19:40.959,0:19:41.869
we're going to see

0:19:42.199,0:19:46.030
that a number of things are the same as they were in part drawings.

0:19:46.469,0:19:46.869
For example,

0:19:46.959,0:19:48.000
the section markers,

0:19:48.079,0:19:49.040
the section views,

0:19:49.160,0:19:50.079
the general nodes,

0:19:50.199,0:19:51.359
the specific notes.

0:19:52.140,0:19:53.609
But we now have a new thing

0:19:53.839,0:19:57.239
that could have existed in a part drawing but it

0:19:57.239,0:19:59.910
didn't exist in our part drawing for the turbocharger.

0:19:59.959,0:20:01.109
It exists in this one,

0:20:01.280,0:20:03.150
so I thought I'd take a second to talk about it

0:20:03.319,0:20:05.109
and that is called the detail view.

0:20:05.439,0:20:07.989
And a detail view is another auxiliary view

0:20:08.280,0:20:11.280
and what it is is it's a zoomed in portion

0:20:11.839,0:20:12.380
of

0:20:12.589,0:20:16.819
the stuff that's inside the detail view marker.

0:20:16.949,0:20:19.420
The detail view marker is that circular

0:20:19.790,0:20:23.099
line that has two arrows on it pointing to a D, in this case,

0:20:23.349,0:20:24.859
and that line is dashed.

0:20:25.150,0:20:26.459
And that tells us

0:20:26.790,0:20:29.979
that we're gonna zoom in on that area, and it's going to appear

0:20:30.280,0:20:33.579
somewhere else on the drawing, and it's going to tell us something that is

0:20:33.910,0:20:36.109
otherwise hard to look at at the size

0:20:36.459,0:20:38.760
that it exists normally in the drawing.

0:20:39.050,0:20:39.380
OK.

0:20:39.489,0:20:42.640
So, that's what you need to know about assembly drawings

0:20:43.010,0:20:43.640
and

0:20:44.050,0:20:46.560
what you need to know about part drawings.

0:20:46.609,0:20:47.040
So,

0:20:47.579,0:20:49.359
before we leave this whole topic,

0:20:49.449,0:20:51.099
I think it's worth saying

0:20:51.329,0:20:52.199
a few things.

0:20:52.530,0:20:54.849
And item number 1 here is

0:20:55.849,0:20:56.599
I hope

0:20:56.829,0:20:59.859
that when you look at the engineering drawings, they won't look

0:20:59.859,0:21:03.339
as daunting as they did before we had this small discussion.

0:21:03.670,0:21:05.020
But what I hope mostly

0:21:05.270,0:21:07.790
is that you'll actually look at the engineering drawings.

0:21:08.170,0:21:10.849
You need to spend some time with the engineering drawings.

0:21:10.920,0:21:11.329
OK.

0:21:11.369,0:21:14.250
I want to spend 5 to 10 minutes with each of the drawings.

0:21:14.290,0:21:14.400
OK.

0:21:14.410,0:21:15.760
We want to examine

0:21:16.130,0:21:16.599
each

0:21:16.849,0:21:19.880
engineering drawing starting with the title block,

0:21:20.130,0:21:21.319
then with the notes

0:21:21.930,0:21:22.959
on page one.

0:21:23.209,0:21:24.969
Then, we want to look at the views,

0:21:25.180,0:21:28.260
try to understand what the views can tell us and why they're there.

0:21:28.489,0:21:31.130
We want to try to envision the geometry.

0:21:32.150,0:21:35.310
We want to do the same then for all those pages.

0:21:35.719,0:21:37.420
And we wanna look for details

0:21:37.719,0:21:42.650
such as specific dimensions or specific details that maybe

0:21:42.650,0:21:44.640
in a detail view or in a section view.

0:21:45.130,0:21:45.650
OK.

0:21:45.859,0:21:47.569
Just as a final recap on here,

0:21:47.579,0:21:48.609
we're after

0:21:49.060,0:21:51.770
getting good at CAD fluency.

0:21:51.900,0:21:57.170
CAD fluency starts by having a good understanding of why you need to create a model.

0:21:57.540,0:22:01.209
That model understanding can come from a variety of places,

0:22:01.430,0:22:03.219
including talking to a client

0:22:03.500,0:22:04.089
or

0:22:04.550,0:22:07.000
following a product development process for a given company.

0:22:07.395,0:22:10.295
In this case, in this course, we're gonna

0:22:10.295,0:22:13.084
have a number of exercises at the beginning here

0:22:13.375,0:22:17.334
where you create geometry that's conveyed to you in an engineering drawing. So,

0:22:17.334,0:22:20.964
you need to learn how to read those engineering drawings. And this video

0:22:21.375,0:22:22.444
demystified them

0:22:22.694,0:22:23.574
just a little bit

0:22:23.814,0:22:25.685
hopefully making them less daunting,

0:22:26.175,0:22:29.214
something you're willing to engage with and to actually read.