What if 3D printing was 100x faster? | Joseph DeSimone

2,365,177 views ・ 2015-03-19

TED


Please double-click on the English subtitles below to play the video.

00:12
I'm thrilled to be here tonight
0
12949
1824
00:14
to share with you something we've been working on
1
14773
2379
00:17
for over two years,
2
17152
2090
00:19
and it's in the area of additive manufacturing,
3
19242
2554
00:21
also known as 3D printing.
4
21796
2717
00:24
You see this object here.
5
24513
1718
00:26
It looks fairly simple, but it's quite complex at the same time.
6
26231
3808
00:30
It's a set of concentric geodesic structures
7
30549
3251
00:33
with linkages between each one.
8
33800
2995
00:36
In its context, it is not manufacturable by traditional manufacturing techniques.
9
36795
6002
00:43
It has a symmetry such that you can't injection mold it.
10
43343
3947
00:47
You can't even manufacture it through milling.
11
47290
3589
00:51
This is a job for a 3D printer,
12
51470
2647
00:54
but most 3D printers would take between three and 10 hours to fabricate it,
13
54117
4481
00:58
and we're going to take the risk tonight to try to fabricate it onstage
14
58598
4226
01:02
during this 10-minute talk.
15
62824
2577
01:05
Wish us luck.
16
65401
2039
01:08
Now, 3D printing is actually a misnomer.
17
68350
3274
01:11
It's actually 2D printing over and over again,
18
71624
3775
01:15
and it in fact uses the technologies associated with 2D printing.
19
75919
3842
01:20
Think about inkjet printing where you lay down ink on a page to make letters,
20
80401
4959
01:25
and then do that over and over again to build up a three-dimensional object.
21
85360
4986
01:30
In microelectronics, they use something
22
90346
2071
01:32
called lithography to do the same sort of thing,
23
92417
2320
01:34
to make the transistors and integrated circuits
24
94737
2208
01:36
and build up a structure several times.
25
96945
2052
01:38
These are all 2D printing technologies.
26
98997
2402
01:42
Now, I'm a chemist, a material scientist too,
27
102099
3888
01:45
and my co-inventors are also material scientists,
28
105987
2724
01:48
one a chemist, one a physicist,
29
108711
2299
01:51
and we began to be interested in 3D printing.
30
111010
2926
01:53
And very often, as you know, new ideas are often simple connections
31
113936
5595
01:59
between people with different experiences in different communities,
32
119531
3743
02:03
and that's our story.
33
123274
1477
02:05
Now, we were inspired
34
125591
2531
02:08
by the "Terminator 2" scene for T-1000,
35
128122
4771
02:12
and we thought, why couldn't a 3D printer operate in this fashion,
36
132893
4943
02:18
where you have an object arise out of a puddle
37
138426
3936
02:23
in essentially real time
38
143052
2468
02:25
with essentially no waste
39
145520
2229
02:27
to make a great object?
40
147749
2322
02:30
Okay, just like the movies.
41
150071
1417
02:31
And could we be inspired by Hollywood
42
151488
3389
02:34
and come up with ways to actually try to get this to work?
43
154877
3507
02:38
And that was our challenge.
44
158384
2066
02:40
And our approach would be, if we could do this,
45
160450
3367
02:43
then we could fundamentally address the three issues holding back 3D printing
46
163817
3854
02:47
from being a manufacturing process.
47
167671
2415
02:50
One, 3D printing takes forever.
48
170086
2531
02:52
There are mushrooms that grow faster than 3D printed parts. (Laughter)
49
172617
5224
02:59
The layer by layer process
50
179281
2136
03:01
leads to defects in mechanical properties,
51
181417
2902
03:04
and if we could grow continuously, we could eliminate those defects.
52
184319
3947
03:08
And in fact, if we could grow really fast, we could also start using materials
53
188266
5132
03:13
that are self-curing, and we could have amazing properties.
54
193398
4644
03:18
So if we could pull this off, imitate Hollywood,
55
198042
4109
03:22
we could in fact address 3D manufacturing.
56
202151
2761
03:26
Our approach is to use some standard knowledge
57
206702
3251
03:29
in polymer chemistry
58
209953
2600
03:32
to harness light and oxygen to grow parts continuously.
59
212553
6599
03:39
Light and oxygen work in different ways.
60
219152
2947
03:42
Light can take a resin and convert it to a solid,
61
222099
3042
03:45
can convert a liquid to a solid.
62
225141
2154
03:47
Oxygen inhibits that process.
63
227295
3534
03:50
So light and oxygen are polar opposites from one another
64
230829
3251
03:54
from a chemical point of view,
65
234080
2508
03:56
and if we can control spatially the light and oxygen,
66
236588
3413
04:00
we could control this process.
67
240001
1947
04:02
And we refer to this as CLIP. [Continuous Liquid Interface Production.]
68
242288
3451
04:05
It has three functional components.
69
245739
1876
04:08
One, it has a reservoir that holds the puddle,
70
248465
3861
04:12
just like the T-1000.
71
252326
1879
04:14
At the bottom of the reservoir is a special window.
72
254205
2416
04:16
I'll come back to that.
73
256621
1491
04:18
In addition, it has a stage that will lower into the puddle
74
258112
3780
04:21
and pull the object out of the liquid.
75
261892
2589
04:24
The third component is a digital light projection system
76
264481
3804
04:28
underneath the reservoir,
77
268285
2020
04:30
illuminating with light in the ultraviolet region.
78
270305
3273
04:34
Now, the key is that this window in the bottom of this reservoir,
79
274048
3223
04:37
it's a composite, it's a very special window.
80
277271
2879
04:40
It's not only transparent to light but it's permeable to oxygen.
81
280150
3646
04:43
It's got characteristics like a contact lens.
82
283796
2659
04:47
So we can see how the process works.
83
287435
2281
04:49
You can start to see that as you lower a stage in there,
84
289716
3414
04:53
in a traditional process, with an oxygen-impermeable window,
85
293130
4179
04:57
you make a two-dimensional pattern
86
297309
1839
05:00
and you end up gluing that onto the window with a traditional window,
87
300008
3362
05:03
and so in order to introduce the next layer, you have to separate it,
88
303370
3552
05:06
introduce new resin, reposition it,
89
306922
3529
05:10
and do this process over and over again.
90
310451
2459
05:13
But with our very special window,
91
313400
1834
05:15
what we're able to do is, with oxygen coming through the bottom
92
315234
3329
05:18
as light hits it,
93
318563
1253
05:21
that oxygen inhibits the reaction,
94
321256
2670
05:23
and we form a dead zone.
95
323926
2624
05:26
This dead zone is on the order of tens of microns thick,
96
326550
4319
05:30
so that's two or three diameters of a red blood cell,
97
330869
3227
05:34
right at the window interface that remains a liquid,
98
334096
2531
05:36
and we pull this object up,
99
336627
1950
05:38
and as we talked about in a Science paper,
100
338577
2392
05:40
as we change the oxygen content, we can change the dead zone thickness.
101
340969
4713
05:45
And so we have a number of key variables that we control: oxygen content,
102
345682
3692
05:49
the light, the light intensity, the dose to cure,
103
349374
3065
05:52
the viscosity, the geometry,
104
352439
1962
05:54
and we use very sophisticated software to control this process.
105
354401
3416
05:58
The result is pretty staggering.
106
358697
2763
06:01
It's 25 to 100 times faster than traditional 3D printers,
107
361460
3736
06:06
which is game-changing.
108
366336
1834
06:08
In addition, as our ability to deliver liquid to that interface,
109
368170
4336
06:12
we can go 1,000 times faster I believe,
110
372506
3740
06:16
and that in fact opens up the opportunity for generating a lot of heat,
111
376246
3557
06:19
and as a chemical engineer, I get very excited at heat transfer
112
379803
4063
06:23
and the idea that we might one day have water-cooled 3D printers,
113
383866
4179
06:28
because they're going so fast.
114
388045
2392
06:30
In addition, because we're growing things, we eliminate the layers,
115
390437
4063
06:34
and the parts are monolithic.
116
394500
1974
06:36
You don't see the surface structure.
117
396474
2090
06:38
You have molecularly smooth surfaces.
118
398564
2493
06:41
And the mechanical properties of most parts made in a 3D printer
119
401057
4240
06:45
are notorious for having properties that depend on the orientation
120
405297
4296
06:49
with which how you printed it, because of the layer-like structure.
121
409593
3761
06:53
But when you grow objects like this,
122
413354
2345
06:55
the properties are invariant with the print direction.
123
415699
3669
06:59
These look like injection-molded parts,
124
419368
2949
07:02
which is very different than traditional 3D manufacturing.
125
422317
3412
07:05
In addition, we're able to throw
126
425729
3530
07:09
the entire polymer chemistry textbook at this,
127
429259
3576
07:12
and we're able to design chemistries that can give rise to the properties
128
432835
3991
07:16
you really want in a 3D-printed object.
129
436826
3042
07:19
(Applause)
130
439868
1337
07:21
There it is. That's great.
131
441205
3234
07:26
You always take the risk that something like this won't work onstage, right?
132
446049
3578
07:30
But we can have materials with great mechanical properties.
133
450177
2879
07:33
For the first time, we can have elastomers
134
453056
2438
07:35
that are high elasticity or high dampening.
135
455494
2461
07:37
Think about vibration control or great sneakers, for example.
136
457955
3413
07:41
We can make materials that have incredible strength,
137
461368
2610
07:44
high strength-to-weight ratio, really strong materials,
138
464828
3576
07:48
really great elastomers,
139
468404
2113
07:50
so throw that in the audience there.
140
470517
2725
07:53
So great material properties.
141
473242
2636
07:55
And so the opportunity now, if you actually make a part
142
475878
3415
07:59
that has the properties to be a final part,
143
479293
3680
08:02
and you do it in game-changing speeds,
144
482973
3100
08:06
you can actually transform manufacturing.
145
486073
2787
08:08
Right now, in manufacturing, what happens is,
146
488860
2856
08:11
the so-called digital thread in digital manufacturing.
147
491716
2962
08:14
We go from a CAD drawing, a design, to a prototype to manufacturing.
148
494678
5039
08:19
Often, the digital thread is broken right at prototype,
149
499717
2723
08:22
because you can't go all the way to manufacturing
150
502440
2432
08:24
because most parts don't have the properties to be a final part.
151
504872
3715
08:28
We now can connect the digital thread
152
508587
2391
08:30
all the way from design to prototyping to manufacturing,
153
510978
4249
08:35
and that opportunity really opens up all sorts of things,
154
515227
2949
08:38
from better fuel-efficient cars dealing with great lattice properties
155
518176
4953
08:43
with high strength-to-weight ratio,
156
523129
1951
08:45
new turbine blades, all sorts of wonderful things.
157
525080
3428
08:49
Think about if you need a stent in an emergency situation,
158
529468
5155
08:54
instead of the doctor pulling off a stent out of the shelf
159
534623
3970
08:58
that was just standard sizes,
160
538593
2229
09:00
having a stent that's designed for you, for your own anatomy
161
540822
4156
09:04
with your own tributaries,
162
544978
1811
09:06
printed in an emergency situation in real time out of the properties
163
546789
3249
09:10
such that the stent could go away after 18 months: really-game changing.
164
550038
3439
09:13
Or digital dentistry, and making these kinds of structures
165
553477
4156
09:17
even while you're in the dentist chair.
166
557633
3181
09:20
And look at the structures that my students are making
167
560814
2716
09:23
at the University of North Carolina.
168
563530
1974
09:25
These are amazing microscale structures.
169
565504
2809
09:28
You know, the world is really good at nano-fabrication.
170
568313
2996
09:31
Moore's Law has driven things from 10 microns and below.
171
571309
4290
09:35
We're really good at that,
172
575599
1602
09:37
but it's actually very hard to make things from 10 microns to 1,000 microns,
173
577201
4040
09:41
the mesoscale.
174
581241
2020
09:43
And subtractive techniques from the silicon industry
175
583261
2833
09:46
can't do that very well.
176
586094
1416
09:47
They can't etch wafers that well.
177
587510
1649
09:49
But this process is so gentle,
178
589159
1950
09:51
we can grow these objects up from the bottom
179
591109
2485
09:53
using additive manufacturing
180
593594
1996
09:55
and make amazing things in tens of seconds,
181
595590
2253
09:57
opening up new sensor technologies,
182
597843
2089
09:59
new drug delivery techniques,
183
599932
2485
10:02
new lab-on-a-chip applications, really game-changing stuff.
184
602417
3732
10:07
So the opportunity of making a part in real time
185
607149
4834
10:11
that has the properties to be a final part
186
611983
2833
10:14
really opens up 3D manufacturing,
187
614816
2976
10:17
and for us, this is very exciting, because this really is owning
188
617792
3200
10:20
the intersection between hardware, software and molecular science,
189
620992
6597
10:27
and I can't wait to see what designers and engineers around the world
190
627589
4166
10:31
are going to be able to do with this great tool.
191
631755
2274
10:34
Thanks for listening.
192
634499
2119
10:36
(Applause)
193
636618
5109
About this website

This site will introduce you to YouTube videos that are useful for learning English. You will see English lessons taught by top-notch teachers from around the world. Double-click on the English subtitles displayed on each video page to play the video from there. The subtitles scroll in sync with the video playback. If you have any comments or requests, please contact us using this contact form.

https://forms.gle/WvT1wiN1qDtmnspy7