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36C3 preroll music
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Herald Angel Noujoum: Hello and
welcome to our next talk,
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Why 3D printing clothes is NOT the future.
Short question to the audience:
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Who of you has already 3D printed anything?
Please raise your hand.
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That's what I thought, I estimate that's about
80 % of the audience in this hall.
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I am not surprised, it is the topic of this talk,
that's why you are here.
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Second question: Who of you
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has already tried 3D printing clothes?
Please raise your hand again.
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I see four people.
So, how did it go?
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One person indicates
that it worked out well,
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the others are showing hand gestures
of "not that well".
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Who of all the people that have
already 3D printed
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has thought about printing clothes?
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Ok, about 10 people have thought
about that.
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Our next speaker, Rebekka, will tell you
why it might not be the best idea
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to 3D print clothes.
On the internet
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and especially Twitter, Rebekka is known
by her nickname Kurfuerstin
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and she is a clothing technician. Her
research includes
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traditional apparel production, she has
worked in a fashion company,
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at the theater and at a tv show.
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Also, she is researching innovative
techniques such as 3D printing
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and virtual clothing simulation,
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meaning software that realistically
simulates clothes
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on a virtual avatar.
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Have fun with the talk ,
I hope you will learn a lot
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and please welcome Rebekka
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with a round of applause.
Thank you.
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applause
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Speaker Rebekka/Kurfuerstin: I just
received some mail really quick,
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but that won't stop me from giving
my talk. Welcome,
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nice to see you all here, in this hall
and on the live stream and...
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additional mail, okay, a lot happening
on this stage. I will maybe read that later,
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but it is great to know that the
post office system works!
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The title of my talk is "Why 3D printing
clothes is NOT the future".
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It will be about the properties of
3D printed clothes and
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what would need to happen in order
for it to be a serious alternative
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for everyday wear. I was just introduced
as a clothing technician.
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In case you don't know what this strange
combination of words means,
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clothes and technology,
a short explanation.
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When clothes are made, at one side,
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you have the design, the idea.
But the realization, the production,
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happens somewhere else entirely
and by some other person.
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In a simplified way, a person creates
the design for a dress
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and says: I designed this dress.
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So they have a nice picture from which
you can learn some information, but not much.
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And they go to a factory and say:
please make this dress.
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The production will kindly ask:
where is the table of information?
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Because the production site wants to
have all the information about the dress.
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And the designer then asks: what?
And the production then asks: what?
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And that would be the end of it.
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Because the factory wants to know,
which fabric do we need for the dress,
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and how much? Which sizes will be made,
and how many dresses in which sizes?
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Which machines do we need for that, what
text will be on the care instruction labels
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and what will be the exact position of the
labels on the side seam in cm?
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All those questions cannot be answered
by the illustration of the dress.
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And that is where clothing technology comes in,
as the intersection between design and production.
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It's about the technical feasibility and
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what needs to be done
to manufacture clothes.
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It's about materials, quality,
prices and locations.
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Where should the production take place,
and when?
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All these questions need answers
and that is the responsibility
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of clothing technicians.
And this kind of reality check,
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the perspective of feasibility, is the perspective
I also chose to examine 3D printing.
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If you search for the words "3D print" and
"clothes", you will get headlines like these.
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For example: 3D printing will bring
flexibility into the fashion industry.
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Or: The fashion of the future. Or: Will the
street wear of the future be 3D printed?
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Or: Can 3D printing fundamentally
change the fashion industry?
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A few years ago, the headlines were
even more sensational.
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They were predicting that by 2020, we
would print a sweater in the morning,
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melt it down in the evening and then
print a new one the next day.
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Nowadays, the predictions have
become a bit more careful,
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at least with a question mark at the end.
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But even from these headlines,
you get the sense that something
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will fundamentally change the
fashion industry.
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There is also the hope of
a sustainable production
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with the argument, that the procedure
of 3D printing is sustainable.
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Sustainability is a major topic
in the fashion industry.
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The question is if 3D printing
might be the solution.
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Clothes have already been 3D printed,
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it's not even that new or unrealistic.
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There are entire 3D printed collections and
I will show some examples now.
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In Israel, Danit Peleg printed her entire
final collection of five outfits.
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In Israel, Danit Peleg printed her entire
final collection of five outfits.
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One example is the two piece outfit on
the right, a top and a floor length skirt.
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The skirt has been printed using
only desktop printers,
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meaning that it consists of
modules of A4 size
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that have been connected afterwards.
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It is flexibel, because it was printed
with a flexible filament,
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but also because it made up
of a zigzag structure
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that allows for it to pull on it.
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If you pull it up, it bounces up and down.
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The jacket is the first
3D printed ready-to-wear
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article of clothing that
you can order online,
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in limited edition of 100 pieces.
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It costs 1500 $.
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You can choose the color and
some writing on the back
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and then the jacket will be
printed in 100 hours.
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Another example is from the
design collective Nervous System,
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who have developed the Kinematics System.
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It consists of triangles
that are connected by hinges,
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making the whole structure flexible.
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But it is made of a hard material.
It can move, but it is not elastic
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and it rattles a bit when you move.
They also developed an opaque version.
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The dress on the right is based
on the same triangle structure,
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but there are some kind of
petals on top of it.
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So the dress is opaque.
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A third example is the Pangolin Dress
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which is also made of a structure
of interlocked modules
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that can move on top of
and into each other,
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thus making the structure flexible.
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You can move in the dress and the
dress adjusts to your movements.
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One of the people working on it is
Travis Fitch, a designer working in New York.
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I contacted Travis and said: I am a
clothing technician, I love numbers.
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How do you know if a newly developed
structure is suitable for a dress?
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How do you know if the elasticity
is high enough
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to use it in a piece of clothing?
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Do you do laboratory tests?
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And he answered, well, I pull at it and then
I either say it is okay or not.
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So the clothing technician in me
came through and said,
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well how about numbers? So I offered
to test some of his structures,
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to conduct some laboratory experiments
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in order to examine how the properties
can be expressed in numbers and units.
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Those were only three examples.
There are many more
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on catwalks and in fashion shows. It is clear
that those examples are not everyday wear.
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They are special made-to-order products,
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it takes months to create them,
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they consist of 300 different pieces
that need to be assembled.
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But the headlines about fundamentally
changing the fashion industry
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are about everyday wear.
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Custom-made items on a catwalk
do not change the whole industry.
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Something needs to happen
before that applies to everyday wear.
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That is why I ask, what kind of properties
do clothes need to have
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in order to be everyday wear,
meaning clothes
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that we can wear every day and
for every occasion?
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First of all, clothes need
to be comfortable.
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There are four aspects of wearing comfort.
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First, the psychological wearing comfort
which is about fashion trends,
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societal norms and individuality.
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The fact that I am standing here
in a t-shirt and a hoodie
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is particularly apt for this congress.
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On another business conference I might
have worn something different.
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And that people are driving around
in onesies and goose costumes
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is also very specific for this group right here.
laughter
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What I mean by this is that people feel
comfortable wearing this in this specific context
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and might not feel at ease
in another context,
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although the clothes themselves
have not changed.
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That is the psychological wearing comfort.
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The next-to-skin-comfort is about
the feeling of something on the skin.
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Surfaces can be soft or scratchy,
they can also cause allergies.
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So it is about the direct contact
on the skin.
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The physiological wearing comfort is very
important as well. It's about the climate control
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of the body and about how clothes can keep
us warm but also allow for moisture to evaporate.
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The human body has this amazing system
of protecting us from overheating.
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We start to sweat and
the moisture evaporates.
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But the evaporation has to happen
through the fabric of our clothes.
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Some clothes allow for better evaporation
than others.
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This aspect is incredibly important for our
comfort when wearing clothes.
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The fourth aspect is the
ergonomical wearing comfort
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which is about freedom of movement
and that is what I examined in detail.
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Freedom of movement in clothes is
achieved by the fit of a piece of clothing,
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mainly meaning how tight it is on the body.
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Secondly, it is achieved by the elasticity
of the materials used.
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This is very important because there are parts
of our body where we need 50% stretching,
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for example at our knees and elbows.
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If you move your arm like this, then the
clothes need to allow this movement
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without tearing apart.
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Without elasticity,
the sleeve would be destroyed
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or would change its form and create buckles.
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If we have a very tight sleeve
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made from a material that is not elastic
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the sleeve at the elbow would take
the shape of our elbow.
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So we need a material with
the capability to rebound.
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After we have moved the arm like this,
the sleeve at the elbow
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will go back to its original shape.
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So if a material is not elastic,
it is not that suitable for clothes.
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It is possible, but then it needs to be
compensated by the cut of the clothes,
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in that case, it cannot be too tight.
If a piece of clothing is loose fit,
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the elasticity of the fabric
is not that important.
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I wanted to examine the influencing
factors on the elastic properties
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of 3D printed structures in order
to actively influence the elasticity.
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This could be used
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to enhance the wearing comfort
of 3D printed clothes
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and thereby get us a bit closer to
3D printed everyday wear.
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Elasticity in textile structures, fabrics,
is achieved by two aspects.
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First, a material itself can be elastic.
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In fabrics, this is mostly elastane.
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Elastane can be stretched 300%
and will return to its original length.
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It is used in a majority of clothes,
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mostly in the ratio 98% cotton and 2% elastane.
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2% are enough to make a shirt
elastic enough to easily put it on
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while at the same time being tight
and not starting to buckle after wearing.
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The second possibility is structural elasticity.
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In clothing, this is mainly achieved
by creating knitwear.
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If you pull at knitwear,
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the loops will change their shape.
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In this manner,
you can create an elastic structure,
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even with materials with low elasticity.
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For example, cotton fibers are
not very elastic. But if you create a knitwear
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made of cotton threads,
the fabric can be very flexible and elastic.
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In 3D printed structures,
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an elastic material can be used as well,
for example TPU.
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TPU is short for thermoplastic polyurethane.
Polyurethane is a primary part of elastane, too.
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So TPU and elastane have very similar
properties based on their chemical composition.
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Structural elasticity is also possible.
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It is possible to print meshes,
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but you can also create different shapes
like curves, arches, helices or springs.
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In short, shapes that you can
compress or pull at,
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so that you will first pull at the structure
before pulling at the material itself.
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However, the design depends
on the printing method. There are several
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different methods and not all of them are
equally suited to create certain shapes.
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For my research, I focused on two of them.
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First, the FLM,
short for fused layer modeling,
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sometimes also called FDM,
short for fused deposition modeling.
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You heat a thermoplastic filament
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and push it through a nozzle
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The nozzle then lays the strand of material
on the printing bed.
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All layers on top of each other
make the object.
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If an object has an overhang
like the shape on the left,
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you need support structures.
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In every layer, the extruder will also
build the supporting columns.
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When the object is finished,
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the support structures can be removed.
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This is not a problem for hard materials,
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you can easily break it off
and sand the surface.
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But for elastic materials,
it's a different situation.
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If you pull at it, it will not break off,
but simply stretch.
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So if you want to print elastic shapes
with overhangs or interlockings,
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this method is not recommended.
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The support structures
cannot be broken off,
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they would have to be cut off
with scissors,
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so that would take a long time.
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Interjection: Water soluble support structures!
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Speaker: Yes, good idea, unfortunately
that does not work for TPU yet.
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Waterbased support structures
are usually made of PVA.
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you can remove them with water afterwards.
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But the melting temperatures
of PVA and TPU do not match.
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TPU requires a very high temperature,
I printed with 215°C.
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At this temeprature, PVA is already decomposing,
its melting temperature is lower.
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So it is a good idea, but at the moment
it does not work yet.
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I am sure that something will be developed
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to solve this problem, though.
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The other method is SLS,
short for selective laser sintering.
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An entire layer of powder is laid
on the build plate.
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A laser melts the fine grain powder in order
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to create the desired shape layer by layer.
In this case,
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the powder itself is the support structure,
so you do not need to print
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supporting columns. In the end, the entire
printer is filled with a block of powder
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and somewhere in there,
the object can be found.
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The powder is removed and can be reused.
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For my research,
I examined several structures.
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The ones on the left and in the middle
are created from powder.
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So it was possible to create some height
and chain-like shapes.
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I had different sizes.
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The smaller size is much more flexible,
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you can easily move it and fold it.
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The modules can be shifted
into each other.
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You can compress it and pull at it
and the structure is very flexible.
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As I said, for the other 3D printing method,
the possibilities in shape were limited.
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This structure is based on a pattern of rhombs
that was extruded.
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If you pull at it, the shape
of the rhomb changes
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before the material itself is strained.
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Again, I had different variations in size and height
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in order to examine the influencing factors
on the elastic properties.
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in order to examine the influencing factors
on the elastic properties.
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How can you examine
elastic properties at all?
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How can you examine
elastic properties at all?
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With a so-called tensile test.
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You don't test a piece of clothing,
you only test a fabric swatch.
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The swatch is clamped into a tensile test machine
which then pulls with constant velocity.
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The corresponding software automatically
creates a diagram like the one on the right.
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It shows the elongation in %,
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meaning how long the fabric swatch
has been stretched,
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and on the other axis
the tensile strength in N,
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how much strength is needed in order to
achieve this elongation of the fabric swatch.
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This diagram shows the elongation,
the elasticity and the tensile strength.
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I need to stress that elongation and
elasticity is not the same.
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You can stretch something and it
might have just gotten longer.
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If I stretch something
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and it returns to its original length,
it is elastic.
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So that is a different property,
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which you can also gather
from the stress-elongation-diagram.
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I tested all of my structures this way.
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Of course, you need to test several specimen
in order to generate average values.
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So I had my numbers and units.
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But what do I do with that?
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I still need to know if these numbers are
good or bad. There is a recommendation
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by the Dialog Textil Bekleidung in cooperation
with the German Fashion Mode Verband,
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It is not a standard or a law,
clothes do not have to have these properties.
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But it is a recommendation, what stretch properties
clothing should approximately have
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and what kind of forces
they should withstand.
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This is a small extract.
It is divided by products,
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so trousers and skirts have different
specifications opposed to underwear.
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If it is far from the body, meaning loose fit,
lower tensile strengths suffice.
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If a piece of clothing is loose fit,
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the stretching properties
are not that important.
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So I compared these numbers to mine
and I found
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that the elongations of my structures
were great.
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But the maximum force was not reached.
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So I can stretch my structures just fine,
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but I do not need a lot of force to tear
them apart and that is a bad result.
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If I bend my elbow
and the sleeve is destroyed,
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I do not want to use this structure
for clothes.
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So the tensile strength of the
3D printed structures is lower
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than the recommended
properties for clothes.
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I also wanted to examine the influencing
factors on the elastic properties.
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From my results, I could see that the size of
the modules influences the properties.
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The larger sizes show higher values
than the smaller variations.
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However, the larger variations do
not feel and move like fabric.
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The smaller variations are
more fabric-like,
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but they didn't show very good
tensile strengths.
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Aside from that, there was another
influencing factor: the slicing software.
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The slicing software has two main tasks.
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Firstly, it slices the object into layers. Secondly,
it transfers the information to the 3D printer,
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where the extruder has to be in order to
create the shape of each layer.
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For example, if you want to print a vase
like the one on the left, the first layer
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would be filled completeley, because we want
to fill the vase with water and it should not leak.
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The path of the extruder could look like this,
it would go in rows
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from one side to the other in order to
completely fill the circle.
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The second layer would be a ring
and the extruder might
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take a path like this, but a different
path is also possible.
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There are many different slicing programs
with many setting options.
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I took a closer look and I found
that the extruder
-
took a very specific path for
my rhomb structures.
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It went to the intersection and then
turned around. Under the microscope,
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you can see that this is exactly the place
where the structure was torn apart.
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The extruder did not cross the
intersection even once.
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At this point, the strands of material
are only connected when a new,
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hot strand melts a little bit into
the other, already cold one.
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But due to the fact that the extruder
did not cross the intersection, it created
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a predetermined breaking point. That
is exactly where the structure was torn apart.
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In another variation that was based on the
same shape, the slicing software decided
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something else. The extruder took the path
to the bending point of the rhomb.
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Consequently, this is the point
where it was torn apart.
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That is why the test samples look
differently after the tensile test.
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That also explains the low tensile
strength of the structures.
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The tensile test machine did not pull at the
material as much as at these connection points
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and depending on how strong these are,
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the structure can be torn apart easily.
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This means that the method itself
limits the tensile strength.
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Now, I tested eight different structures,
eight different variations.
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You might ask now how I came to the
conclusion that 3D printing clothes
-
is not recommended in general.
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Maybe a different structure would show
a higher tensile strength.
-
Yes, maybe. But the method itself creates
limitations concerning the properties.
-
We have to go deeper and look
at the molecules.
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Textile fibers naturally have a
very high tensile strength.
-
On the inside, natural fibers like cotton,
wool or linen show a regular
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arrangement of molecular chains.
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There are amorphous parts
and crystalline parts.
-
The strands that you can see on the
right depict molecular chains.
-
The amorphous parts,
where the molecules are
-
tangled like a plate of spaghetti,
are not stable.
-
The crystalline parts, where they show a
regular arrangement, are stable.
-
Natural fibers show a high degree of
crystalline parts which translates
-
to a high tensile strength. Fibers naturally
show higher tensile strengths
-
than my 3D printed structures
could ever have.
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And for synthetic fibers, there are
measures we can take to even influence
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and increase the tensile strength.
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There are several ways to spin a fiber,
at least one of them is very similar to 3D printing.
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You melt synthetic material and press it
through a nozzle.
-
The extruded strand is the fiber.
-
The difference is that you have several
possibilities to influence the property
-
of the extruded strand or fiber.
-
The degree of crystallinity depends on
the rate of controlled cooling.
-
The slower a fiber cools off the more
time do the molecular chains have
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to arrange themselves regularly.
-
That is why the spinning chambers
are really hot
-
in order to allow for a very slow rate
of controlled cooling
-
so that the fibers show high degrees of
crystallinity, resulting in high tensile strengths.
-
We do not have this opportunity
in 3D printing.
-
We can use a heated build plate. But that
-
only influences the first few layers.
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Besides, we need the printed strands to
-
cool off quickly so that they keep their shape.
-
We can only print the next layer
-
if the layer underneath
has already hardened.
-
We cannot keep a constant high temperature
like we can in the spinning chamber.
-
The SLS method allows
for better conditions
-
concerning the tensile strength
-
and the structures did show better values.
-
We have a second possibility to increase the
tensile strength of synthetic fibers
-
which is by stretching them
after spinning.
-
The fibers are guided through cylinders
and subjected to tensile forces.
-
This increases the degree of
crystallinity even more.
-
The molecules are forced
to align even more.
-
This decreases the fiber diameter and
makes the fiber more fine, softer
-
and at the same time stronger.
-
That explains why textile fibers have
much higher tensile strengths
-
while at the same time being much finer
than anything you can 3D print at the moment.
-
Furthermore, textile fibers have the advantageous
capability of warming us by isolating air.
-
Every little chamber that can entrap air
turns a fabric into a warming structure
-
when worn on the body.
Fabrics consist of threads
-
and threads consist of fibers,
-
as you can see on this microscope picture.
-
It's not a picture of a carpet,
it's fabric
-
and the little single fibers would not be
visible with the naked eye.
-
The gaps between the fibers
isolate air.
-
At the same time, the gaps are important
for the transportation of moisture.
-
Sweat can evaporate and go through the fabric.
In conclusion,
-
fabrics can warm us and at the same time
protect us against overheating.
-
At the moment, we cannot 3D print such fine
miniature fibers. We are still quite limited
-
when it comes to fineness. We cannot efficiently
3D print chambers to entrap air
-
like the ones we can find in fabrics
made of textile fibers.
-
Some things cannot be done yet
in 3D printing. But what can we do
-
in 3D printing instead? We have an immense
freedom of design that can be applied
-
mostly in shoes and accessories,
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for example bracelets, necklaces
or glasses.
-
The benefits can be used for costumes.
-
For example, in the movie "Black Panther",
several crowns were 3D printed.
-
Theoretically, the process is sustainable,
-
just because it is additive manufacturing.
-
Material is only built where it is needed
for the desired shape.
-
This is in stark contrast to the
production of clothes.
-
When you cut the fabric, you can achieve
a utilization ratio of maybe 90%.
-
Just because pattern pieces
have many different shapes,
-
10% of the fabric is thrown away.
-
3D printing is more sustainable
in this aspect.
-
Also, the materials can be reused.
-
Recycling is another problem
in the fashion industry.
-
So it is a good thing that you can
reuse the powder after printing.
-
3D printing is also very suitable for
made-to-order production.
-
In the fashion industry, made-to-order
items always lead to high costs.
-
Also, it is possible to create different
material properties in the same product.
-
When I have the shoulder
-
and want it to be a bit more firm,
-
I can already prepare that in the
3D model. I can decide
-
to create more layers. If I created the same
piece of clothing in fabric,
-
I would need to have a seam, I would reinforce
it with another fabric
-
or another layer of fabric. Using a 3D printer,
this could happen in the same step.
-
Theoretically, it is also possible to
integrate additional functions
-
like cables, LED or sensors.
-
There is still a question mark
behind that.
-
First of all, this would not
be everyday wear,
-
and secondly, this is not
state of the art yet.
-
Another benefit might be to create the
whole garment in one step.
-
Right now, a fabric is created out of
threads out of textile fibers.
-
Then, the fabric needs to be cut, the
pieces need to be sewn together,
-
maybe it is dyed after that.
Different processes,
-
executed at different locations.
With 3D printing,
-
everything could happen in the same step.
-
But only if the garment can fit into
the build volume of a printer.
-
If we print A4 sized pieces and
assemble them afterwards,
-
we are still in the same situation of
having to connect many pieces.
-
The software developed by Nervous System
is a smarter solution.
-
The software digitally folds the dress.
The dress is then printed in the folded state,
-
significantly reducing
the needed build volume.
-
The dress is hidden somewhere
in the block of powder.
-
The powder is removed,
a bit like in archeology,
-
the dress will get cleaned off
and opened.
-
This is a good option to really
use the benefits of 3D printing.
-
The disadvantages or challenges are
-
the insufficient tensile strength,
resulting from the process itself
-
and there is not a lot we can
do about it. We are still very limited
-
in terms of fineness. The standard nozzle
diameter is 0.4 millimeters.
-
Fiber diameters are more
in the micrometer range.
-
That is a significant difference. The fineness
is very important for the next-to-skin-comfort,
-
for the transportation of moisture and for
the capability to warm us.
-
This is fundamental and without it,
the aspects of wearing comfort
-
cannot be guaranteed
when we 3D print textile structures.
-
Time and costs are still
quite problematic in 3D printing.
-
It takes af long time
and it is very expensive.
-
Again, this is not suitable for
everyday wear, only for individual pieces.
-
We also still have to discuss
care instructions.
-
Can you wash a 3D printed garment
at all? If I wear a piece of clothing every day,
-
I want to be able to wash it.
-
When we talk about garments,
we also need to talk about fastenings,
-
you need to somehow get inside
the piece of clothing.
-
So, zippers, buttons, hooks, eyelets,
all of this needs to be thought of
-
if we want to print
everything in one piece.
-
In conclusion, the construction of fabrics
made from threads made from fibers
-
is still unbeatable in regards of
wearing comfort.
-
There are not yet applicable solutions
-
to imitate the properties in 3D printing.
-
At the current state of the art,
3D printed clothes are not only not the future,
-
they aren't even the present.
Because the present means
-
fabrics made of textile fibers and that
works really well for our wearing comfort.
-
3D printed structure cannot
provide that yet.
-
That does not mean that we
should stop the research.
-
Whoever said before that they had
success when printing clothes,
-
I am very interested to hear about that.
Maybe there are some aspects
-
that I have not thought about.
But we should not forget
-
the basic function of clothes. The 3D
printed clothes that I showed in the beginning,
-
those are amazing artworks, I love
them and I want to see more of them.
-
But I want to remind everyone that
clothes should warm us,
-
that in general, it should be opaque
and that the climate exchange
-
and the transportation of moisture has
to be guaranteed. I find it a bit difficult
-
to put so much hope on 3D printing
-
to fundamentally change
the whole fashion industry.
-
Because the fashion industry has
a lot of serious problems,
-
ecological problems,
-
but also social and societal problems.
-
But I don't think we should simply hope
to develop new technologies
-
and tell us that the sustainability problem
can be solved by 3D printing
-
all of our clothes. Please conduct
further research.
-
But please don't forget the basic
functions of clothes and do not think
-
that a new technology will solve all the
problems of the fashion industry.
-
I advise everyone
to revolutionize the fashion industry.
-
But please do not think that 3D printing
is the universal solution for that.
-
And now I am finished with my
presentation and I thank you all for listening.
-
applause
-
Herald Angel Noujoum: Yes, thank you,
that was quite a precision landing, I'm afraid
-
we don't have time left for questions, I am sorry
to everyone flocking to the microphones right now.
-
But you can see here where you can
talk to Rebekka,
-
you can find her and ask her questions
on Twitter under @Kurfuerstin.
-
You can also talk to her right now after
the talk. Maybe not right here,
-
but somewhere in the back.
She also needs to read her post cards.
-
I'm sure there will be time
and the possibility
-
to talk to her or each other about
3D printing and 3D printed clothes.
-
Please give another round of applause.
-
applause
-
postroll music
-
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