APPLE SKIN™ BECOMES · Le Pli – KOHPA® wireless lamp Sascha dos Santos and Tilmann Stud insky...
Transcript of APPLE SKIN™ BECOMES · Le Pli – KOHPA® wireless lamp Sascha dos Santos and Tilmann Stud insky...
APPLE SKIN™Vegan leather from
apple pomace
AppleSkin™ is a bio-based
alternative to leather, combining
performance and circularity with
‘Made in Italy’ quality.
ORGANIC WASTE BECOMES
FASHIONABLE
European Commissionwww.ec.europa.eu/info/research-and-innovation_en
Concept & Designwww.lekkerwerken.designwww.haute-innovation.com
Realisationwww.triplea.be
© European Union, 2020
Materials impact the environment, society and economy. Under Horizon 2020, the EU‘s research and innovation programme, about €2 billion in EU funding, has supported research in advanced materials.
More information on EU funding:https://europa.eu/!MJ49rK
PLANT-BASED LEATHER ALTERNATIVE WITH A LOW CARBON FOOTPRINT
According to figures from the German Federal Ministry for the Environment (2016), consuming one kilogramme of fresh pork releases around 3.25 kg of carbon dioxide into the atmosphere; for beef, it is even more – 13.31 kg of Greenhouse Gas emissions. To reduce CO₂ emissions, it is therefore recommended to reduce meat consumption. This development also affects some of the by-products of the meat industry, such as leather. In recent years, a completely new industrial sector for the production of vegan leather alternatives with high growth rates has been established in the EU. One of the protagonists of this new sector is the company Frumat from Bolzano in South Tyrol.
The region in north Italy is renowned for its apple processing industry which is faced with a significant amount of organic waste. Frumat’s founder Hannes Parth came up with the idea to develop a plant leather-like alternative from apple pomace. AppleSkin™ consists mostly from organic residues such as stems, seeds, apple peels and fibers. The residues are first dried, transferred to a fine cellulose powder, mixed with a bioplastic and applied in layers to a carrier such as cotton.
Frumat® was born out of the idea of recycling industrial organic waste and trans-forming it into raw materials.Hannes Parth, CEO Frumat
At temperatures of around 130 °C, the materials fuse together. A variety of textures and thicknesses are achieved by fi nal embossing or laser processing. AppleSkin™ can be easily personalised and produced on demand. Currently, the material is being used in the fashion and furnishing industries. A particularly thick variant of the material from 50 % recycled apple pomace and 50 % polyurethane is used in shoe manufacture, for bags and upholstery. At the moment, Frumat is working on a cellulose-based leather alternative for the automotive sector.
More benefi tsHannes Parth off ers an ecological, high performing alternative to animal leather. The new raw material answers both the local apple-waste issue and the increasing demand for vegan leather alternative with a low carbon footprint.
WANT TO LEARN MORE?
ProducerFrumat SrlVia T. A. Edison 1539100 Bolzano Italy
Hannes ParthPhone: +39 471 052635E-mail: [email protected] www.frumat.it
UNFOLD ME
APPLE SKIN™Vegan leather made from apple pomace
APPLE POMACEconsists mainly of cellulose, which is a wonderful raw material for the production of a textile material.
Natural fruit
Appleresidues
Cellulose powder
Juices and jam
UPCYCLING FROM FOOD WASTE
“We recover the industrial waste of the apple juice production and transform it into new raw materials.”Hannes Parth, CEO Frumat
billion tonnesof waste burned in Europe every yearthat could be raw materials for new products
3AppleSkin™: upcycled, ecological, environmental & animal friendly
@EUScienceInnov#InvestEUResearch#EUGreenDeal
© European Union, 2020
KOHPA®Electrically
conductive paper
A paper made from recycled carbon
and paper fi bers with multiple
applications off ering sustainable
solutions for the environment
and technology.
KOHPA® CONDUCTIVE
PAPER
European Commissionwww.ec.europa.eu/info/research-and-innovation_en
Concept & Designwww.lekkerwerken.designwww.haute-innovation.com
Realisationwww.triplea.be
© European Union, 2020
Materials impact the environment, society and economy. Under Horizon 2020, the EU‘s research and innovation programme, about €2 billion in EU funding, has supported research in advanced materials.
More information on EU funding:https://europa.eu/!MJ49rK
PAPER WITH VARIOUS FUNCTIONS
KOHPA® is the world‘s first paper with electrically conductive functions based on the integration of carbon fibers into the cellulose matrix. The carbon fibers are extracted from composite materials by pyrolytic processing. The resin is removed by sublimation under high temperature and exclusion of oxygen. After the process, the carbon fiber is residue-free for further processing.
Radiation ProtectionIn the course of investigations, one example showed that the electromagnetic radiation (EM radiation) was clearly reduced by the paper structure. It follows that the paper is suitable for electrical shielding or to protect man and beast against electrical, magnetic and EM radiation.
Possible UsesThere are unlimited possibilities in heat emission ranges. Floors and walls are as easily heated as difficult to access areas and complex forms. The maximum advantage is achieved by the low space consumption and the good formability. It is the thinnest and lightest panel heating in the world. The economic efficiency is shown in comparison to conventional heating systems primarily by the radiant heat achieved. This goes hand in hand with energy savings, which lowers heating costs. The carbon paper can also be made waterproof. Wet deformation, different degrees of absorbency and targeted air permeability values can be set according to the corresponding requirements.
Indication Unit Value
Grammage g / m² 75 – 80
Material thickness µm 200 – 250
Air permeability l/m²s 95
Application panel heating
Temperature increase up to °C 30 – 70
Required electrical power W/m² 130 – 200
Application Shielding
Shielding degree % 99 – 99,999
Shielding ef f ectiveness db 20 – 50
The electrical conductivity of KOHPA® can be used to generate light or as surface heating.Walter Reichel, RESO Ober lächentechnik
WANT TO LEARN MORE?
ProducerRESO Oberflächentechnik GmbH Karlstr. 4886415 MeringGermany
Dipl. Ing. Walter Reichel Phone: +49 8233 743 91 75 E-mail: [email protected] www.kohpa.com
Le Pli – KOHPA® wireless lampSascha dos Santos and Tilmann Studinsky have used KOHPA® conductive paper to design a LED lamp that is wireless. Cleverly constructed almost entirely of folded paper, its angular body consists of just 3 paper layers – 2 of which are electrically conductive. The power supply works with a simple wood stand that the paper lamp can be plugged into. This way, apart from the cord providing the stand with power, no cable is needed for Le Pli to function! Installation of the LEDs directly on the paper also keeps the design light and free of non-essential components.
UNFOLD ME
ADVANTAGES OVER CONVENTIONAL HEATING SYSTEMS
easy formability low space requirement
low costs reduced house dust circulation
KOHPA®Electrically conductive paper
@EUScienceInnov#InvestEUResearch#EUGreenDeal
PROTECTIONagainst electro-magnetic fi elds
- 99,5 %
100 % Recycled carbon and
paper fi bers
120°C
TURN ON LIGHT WITH KOHPA®
Can reach SURFACETEMPERATURESof up to
Step 1:Cut the KOHPA® into two strips of equal size and a sheet of normal paper to about 6x18 cm.
Step 4: Press the two KOHPA® strips onto the battery and the lamp will light up.If the LED doesn’t light up, turn the battery around – the current only fl ows in one direction with LED.
Step 3: Attach the enclosed LED to the KOHPA® strips with the wires on one side each. Insert a button cell battery (3V) between the KOHPA® strips.
Step 2:Put the paper in between the KOHPA® strips as insulation. Make sure the paper sticks out slightly at the top and the sides. Fold the uninsulated parts of the KOHPA® outwards, so they don’t touch each other.
© European Union, 2020
NAMIB BEETLE TEXTILE
Harvesting water from fog
Desert beetles and various plants
were models for the development
of a textile for the eff ective
extraction of drinking water
from fog.
EXTRACTING WATER FROM
FOG
ParameterUnitFabric
Area densityg / m²ca. 190
Air permeabilityml / min *dm²ca. 8.450
Burst-bulging test
Bursting pressureKPa142
Bulging heightmm39
Fog separation degree
Relation of separated to perfused amount of water%75 – 85
Pull-elongation propertiesalong/cross
Maximum tensile forceN / 5 cmca. 360 / 260
Maximum tensile force elongation%ca. 44 / 186
European Commissionwww.ec.europa.eu/info/research-and-innovation_en
Concept & Designwww.lekkerwerken.designwww.haute-innovation.com
Realisationwww.triplea.be
© European Union, 2020
Materials impact the environment, society and economy. Under Horizon 2020, the EU‘s research and innovation programme, about €2 billion in EU funding, has supported research in advanced materials.
More information on EU funding:https://europa.eu/!MJ49rK
HIGH-TECH TEXTILE FOR A BETTER QUALITY OF LIFE
What nature has successfully used for thousands of years to survive in arid regions could be an important solution to the increasing water shortage for many people, especially in developing countries. The new high-performance textile is the result of years of bionic research at the DITF Denkendorf. Essedea, a manufacturer of technical 3D textiles, was responsible for the technical production implementation.
The old principle of catching fog by stretching raschel nets has been completely overtaken by the new material: water separation is many times more effective than all previously used two-dimensional nets (the third dimension increases the contact surface with fog), UV resistance even in extremely high solar radiation such as in deserts, and even storms with wind speeds of up to 120 km/h do not limit its functionality. Up to 66 l of water per m² per day can be extracted from fog. In the meantime, the textile has been in continuous use worldwide for several years. The great potential of the material can unfold wherever there is sufficient wind and fog. It can be used for the production of drinking water in areas without access to water sources, but also for the irrigation of large areas of land in agriculture, viticulture or on golf courses, for example.
Our high tech textiles can extensively contribute to a better quality of life for many people worldwide.Team Essedea texolutions
Parameter Unit Fabric
Area density g / m² ca. 190
Air permeability ml / min *dm² ca. 8.450
Burst-bulging test
Bursting pressure KPa 142
Bulging height mm 39
Fog separation degree
Relation of separated to perfused amount of water % 75 – 85
Pull-elongation properties along/cross
Maximum tensile force N / 5 cm ca. 360 / 260
Maximum tensile force elongation % ca. 44 / 186
WANT TO LEARN MORE?
DeveloperGerman Institutes of Textile and Fiber Research Körschtalstr. 2673770 Denkendorf, GermanyDr. Thomas Stegmaier, Dr. Jamal SarsourE-mail: [email protected]
ProducerEssedea GmbH & Co. KGLothforster Str. 5041849 WassenbergGermany
Dirk SchulzePhone: +49 2432 964 461 E-mail: [email protected]
UNFOLD ME
of passing fog is separated to water
ACCESS TO WATERWATER EXTRACTION
TEST IT
up to 66 litersper sqm per day
(many times more effective than conventional materials)
up to 85 %
Today:
1.2 billion people have no access to springs or pipe systems
2025:
2.3 billion people will have no access to springs or pipe systems
Water gaining costs for Namib Textile are calculated from about
2–3 € per 1000 l water
“The water is in the air, you just have to catch it.”
NAMIB BEETLE TEXTILEDrinking water from fog
Dr. Jamal Sarsour, DITF Denkendorf
@EUScienceInnov
#InvestEUResearch
#EUGreenDeal
Observe the drop formation on the sample textile by using a plant sprayer as a substitute for fog
© European Union, 2020
NEPTUTHERM®100 % organic
insulation material
ORGANICINSULATION FORBUILDINGS ANDAPPLICATIONS
NeptuTherm® reduces the loss
of thermal energy in winter
and provides a pleasant coolness
in summer – with the highest
heat storage capacity of all
insulation materials.
ORGANIC INSULATION FOR BUILDINGS ANDAPPLICATIONS
European Commissionwww.ec.europa.eu/info/research-and-innovation_en
Concept & Designwww.lekkerwerken.designwww.haute-innovation.com
Realisationwww.triplea.be
© European Union, 2020
Materials impact the environment, society and economy. Under Horizon 2020, the EU‘s research and innovation programme, about €2 billion in EU funding, has supported research in advanced materials.
More information on EU funding:https://europa.eu/!MJ49rK
In today’s world with [...] the growing awareness of the environment in all sections [...], it is an indispensable must to follow this path in construction as well.NeptuTherm®
SEAGRASS AS A NATURAL INSULATION MATERIAL
Neptune balls are a waste product of seagrass meadows around the Mediterranean Sea and are created by wave movements. The mother plant plays an important role in the global ecosystem, as one hectare stores 10 times more CO₂ and can convert 5 times as much CO₂ into oxygen as the same area of rainforest.
Seagrass characteristicsThe fibres have a high mould resistance, are poorly flammable (B2) and have a measured heat conduction of only 0.039 watts per Kelvin and metre – and all this by nature. These properties make them ideal for sustainable use in the construction industry. In addition, the fibers have an excellent heat storage capacity of over 2,500 joules per kilogramme Kelvin. Neptune grass thus exceeds the heat storage capacity of all known insulation materials.
Disposal in the event of a later demolition is completely unproblematic: if the Neptune fibers are not reused in another building, they can simply be raked into the garden soil as a planting substrate to loosen up the soil.
Parameter Unit Fibres
Thermal conductivity λD W/mK 0.039
Rated value λ (DIN 4108) W/mK 0.046
Heat storage capacity J/kgK > 2,500
Water absorption capacity kg/kg 1.6 to 3.4
100 % organic and completely
free of toxic matter
UNFOLD ME
WANT TO LEARN MORE?
ProducerNeptuGmbH Im Speitel 5676229 KarlsruheGermany
Monika und Michael Meier Phone: +49 721 946 33 49 E-mail: [email protected] www.NeptuTherm.de
NeptuTherm®
Wood-based materials (e.g. Wood fi bre)
Vegetable fi bres and textile fi bres (e.g. Sheep wool)
Synthetic materials (e.g. Styrofoam)
Inorganic building and insulation materials (e.g. Glass wool)
Aluminium
NeptuTherm®NeptuTherm®NeptuTherm®NeptuTherm®
Wood-based materials (e.g. Wood fi bre)Wood-based materials (e.g. Wood fi bre)
NeptuTherm®NeptuTherm®NeptuTherm®
Wood-based materials (e.g. Wood fi bre)
NeptuTherm®NeptuTherm®
Wood-based materials (e.g. Wood fi bre)Wood-based materials (e.g. Wood fi bre)
2,599 J/kg
K
BIOLOGICAL CYCLE If not being reused in another building, the Neptune fi bers
can simply be raked into the garden soil as a planting
substrate to loosen up the soil.
DID YOUKNOW? The German professor of architecture Richard
Meier, an enthusiastic kiter, and his wife Monika
spent their summer holidays in Spain.
While on the beach, they noticed these small
brown felt balls, pulled them apart and examined
them. A friend pointed out to them that the weird
balls were not even good for lighting the fi re.
Immediately, the idea was born to make a heat
insulation out of the wool.
Tests conducted by the Fraunhofer Institute
for Building Physics confi rmed its naturally
outstanding properties.
1 hectare of seagrass stores 10x more carbon dioxide and
can convert 5x as much carbon dioxide into oxygen
as the same area of a tropical rainforest.
NEPTUTHERM®100 % organic insulation material
@EUScienceInnov#InvestEUResearch#EUGreenDeal
2,5002,0001,000[J/kg K]
99,9 %reduced carbon footprint compared to the production of 1kg glass wool
up to
Carbon footprint of
1 kg NeptuTherm®So
urce
: Jam
es C
ook
Uni
vers
ity A
ustr
alia
Sour
ce: F
NR
– Fa
chag
entu
r N
achw
achs
ende
Roh
stoff
e e
. V.,
ww
w.b
aune
tzw
isse
n.de
Sour
ce: F
NR
Rese
arch
Pro
ject
202
0, N
awar
o in
sula
tion
mat
eria
ls,
in c
oope
ratio
n w
ith t
he U
nive
rsity
of
Stut
tgar
t, In
stitu
te IA
BP
SPECIFIC HEAT CAPACITY
Carbon footprint of
1 kg Glass wool
= carbon dioxide = oxygen
© European Union, 2020
O0HO BUBBLESEdible packaging
for liquids
Ooho is a new kind of packaging
made from seaweed that can
contain liquids and semi-liquids
in a naturally biodegradable
membrane.
OOHO! AN INNOVATIVE ALTERNATIVE TO PLASTIC
BOTTLESSource: https://w
ww
.unenvironment.org/interactive/beat-plastic-pollution/
European Commissionwww.ec.europa.eu/info/research-and-innovation_en
Concept & Designwww.lekkerwerken.designwww.haute-innovation.com
Realisationwww.triplea.be
© European Union, 2020
Materials impact the environment, society and economy. Under Horizon 2020, the EU‘s research and innovation programme, about €2 billion in EU funding, has supported research in advanced materials.
More information on EU funding:https://europa.eu/!MJ49rK
OOHO WATER, EDIBLE AND BIODEGRADABLE
Made by Notpla, a start-up pioneering the use of seaweed extracts and plant-based ingredients to create alternative solutions for single-use packaging, Ooho is an edible packaging that can contain beverages and condiment sauces. Oohos are 100 % home compostable in a matter of weeks. Ooho arises from the need to find an alternative to the millions of plastic bottles that are used and discarded every day for water and other beverage consumption. It is important to note that the vast majority is not recycled and ends up damaging the environment.
WHERE DOES THE PLASTIC WASTE GO?
is sent to landfills, dumps or into natural environment
gets incinerated
gets recycled
79 %
12 %
9 %
Sour
ce: h
ttps
://w
ww
.une
nviro
nmen
t.org
/inte
ract
ive/
beat
-pla
stic
-pol
lutio
n/
What is it made of?The way nature encapsulates liquids is truly inspiring. From egg yolks to our own cells, nature uses membranes to protect precious contents from the outside. Ooho has focused its efforts on creating a cost competitive sachet made from an abundant natural resource that disappears as quickly as natural food waste: seaweed. Our material can in fact be treated just like food and disposed of as food waste, but even if it goes in the general waste and ends up in landfill it will degrade to its original elements. The circularity here is in its rawest form of biological recycling, with the material breaking down into basic biological molecules that can be used again by seaweed or other organisms to grow.
We make packaging disappear! Notpla Ltd.
UNFOLD ME
WANT TO LEARN MORE?
ProducerNotpla Limited Unit 8B Queen‘s Yard, White Post Lane, E9 5EN London, UK
Phone: +44 744 993 79 36E-mail: [email protected]
Seaweed is one of nature’s most renewable resources. It grows fast, up to 1 meter per day. It doesn’t compete with food crops for land, unlike biosourced plastics such as polylactic acid (PLA). Seaweed doesn’t need fresh water or fertiliser to grow, it can virtually be farmed or harvested on any coastline. Seaweed is also a great carbon sink. As any plant does, seaweed actively sequesters CO₂ but also participates in the de-acidification of the oceans.
Ooho could massively reduce the waste problem at major events such as concerts, festivals and sporting events by replacing plastic cups and bottles. Notpla provided 35k oohos for the runners of the London Marathon in 2019.
plas
tic
bott
le
O0HO BUBBLESEdible packaging no waste
€
cheap to produce
biodegrades a er 4 – 6 weeks
150 mill
ion
tonn
es of plastic currently circulates in Earth’s marine environments
On average, the lifestyle of every European
leaves about 31 kg of waste material from
plastic packaging per person every year. Since
this has not always been properly recycled or
landfi lled in recent years, plastic waste has
found its way into nature and the oceans in
many places, with a negative impact on our
ecosystems.
The European Commission plans to massively
reduce the amount of plastic waste by 2030.
As a strategy, all plastic packaging should
be recyclable by the end of the decade. 1 m.seabirds per year
are dying of plastic waste
80 %of marine waste has its
origin ashore, about 3/4 of it are made of plastic
WHAT WE LEAVE BEHIND
BENEFITS FOR US AND OUR ENVIRONMENT
@ EUScienceInnov
# InvestEUResearch
# EUGreenDeal
31 kgof plastic waste
within EU per person every year
by 2050
more plastic parts than fi sh will be
fl oating in our seas
up to450 years
endurance of plastic pollution to end up
as microplastics
Sea pollution fi gures source: https://oneearth-oneocean.com/en
© European Union, 2020