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Chairman’s welcome &
introduction
5 July 2017
Dale Walker, Research Analyst, Ellen
Macarthur Foundation
The Role of the
Bioeconomy within
Circular Economy
3
THE ROLE OF THE BIOECONOMY WITHIN THE
CIRCULAR ECONOMY
Core
Philanthropic
Partner:
Global
Partners:
ELLEN MACARTHUR FOUNDATION
INSIGHT &
ANALYSIS
EDUCATION
& TRAINING
BUSINESS &
GOVERNMENT
COMMUNICA-
TIONS
Catalysing circular
activities across the
global economy
Inspiring learners to re-
think the future through
the circular economy
framework
Providing robust
evidence about the
benefits of the circular
economy transition
Engaging a global
audience around the
circular economy
THE CIRCULAR ECONOMY
Minimise systematic
leakage and negative
externalities
Collection Collection
Technical
cycles
Renewables
Biological cycles
Cascades
Biochemical
feedstock
Biogas
Regene-
ration
Extraction of
biochemical feedstock
Product manufacturer
Service provider
Parts manufacturer
Farming/
collection
STRUCTURAL WASTE
92%
50%
86%
25%
50%
100m
PRESSURES ON THE BIOCYCLE
52%
40bn
8m
A SYSTEM THAT WORKS
In the biosphere value can be
abundant and powered by the
sun.
This requires three things:
A SYSTEM THAT WORKS
1. Maintaining the integrity of
natural systems (which are
complex and
interdependent).
A SYSTEM THAT WORKS
2. Returning nutrients
appropriately to the soil.
A SYSTEM THAT WORKS
3. Preventing toxic materials
from entering the system and
accumulating.
REGENERATIVE AGRICULTURE
VALUE FROM BY-PRODUCTS
A SYSTEM THAT WORKS
GW FINDINGS80%
60%30%
1.8tn
CITIES
PROJECT MAINSTREAM
URBAN BIOCYCLES
BIOENERGY BIOREFINERIESNUTRIENTS ENERGY MATERIALS
URBAN BIOCYCLES – SCOPING PAPER
20Core
Philanthropic
Partner:
Global
Partners:
QUESTIONS?
5 July 2017
• Hannah Evans, Strategy Manager – Bioenergy, Energy
Technologies Institute
• Dr Stephen Wise, Associate Director, Environment & Infrastructure,
Amec Foster Wheeler
Brexit: How will it impact the
development of environmental
legislation?
© 2017 Energy Technologies Institute LLP - Subject to notes on page 1
© 2017 Energy Technologies Institute LLP The information in this document is the property of Energy Technologies Institute LLP and may not be copied or communicated to a third party, or used for any purpose other than that for
which it is supplied without the express written consent of Energy Technologies Institute LLP.
This information is given in good faith based upon the latest information available to Energy Technologies Institute LLP, no warranty or representation is given concerning such information,
which must not be taken as establishing any contractual or other commitment binding upon Energy Technologies Institute LLP or any of its subsidiary or associated companies.
Bridging the gap between technological innovation and
market demand
Hannah Evans, Bioenergy Strategy Manager
© 2017 Energy Technologies Institute LLP - Subject to notes on page 1
What is the ETI?
• A public-private partnership between global energy and
engineering companies and the UK Government
• Set up to identify and accelerate the development and
demonstration (and de-risking) of an integrated set of low carbon
technologies
ETI programme associate
ETI members
2.
© 2017 Energy Technologies Institute LLP - Subject to notes on page 1
What does the ETI do?
3.
System level strategic planning
Technology development & demonstration
Delivering knowledge &
innovation
© 2017 Energy Technologies Institute LLP - Subject to notes on page 1
ETI’s ‘ESME’ model indicates an important role for
bioenergy and CCS in the UK
Additional cost of delivering 2050 -80% CO2 energy system NPV £ bn 2010-2050
Chart data from case dc14
• Models pathway
and supply chain
constraints in the
energy system out
to 2050
• Used to model
different scenarios
for meeting the UK’s
2050 GHG targets
• Develops
understanding of
key sectors and
technologies
4.
© 2017 Energy Technologies Institute LLP - Subject to notes on page 1 5
flexible efficient affordable scalable
ETI analysis highlights gasification as a prominent,
scenario resilient technology
Small scale (town) waste
gasification with syngas clean up
is a potentially important technology
with near term deployment
opportunities
Appraise
(2009-11)
EFW project
Select
(2012-13)
Define
(2014-16)
Execute
(2017 +)
WG Phase 1Contract
shaping
WG demo
project
© 2017 Energy Technologies Institute LLP - Subject to notes on page 1 6
ETI analysis highlights gasification as a prominent,
scenario resilient technology
Appraise
(2009-11)
EFW project
Select
(2012-13)
Define
(2014-16)
Execute
(2017 +)
WG Phase 1Contract
shaping
WG demo
project
MRF GasifierSyngas
clean upPower
Competition – 3 designs
FEED study and Business Plan
Has to demonstrate high efficiency
(net >25%) and availability (>80%)
© 2017 Energy Technologies Institute LLP - Subject to notes on page 1 7
ETI analysis highlights gasification as a prominent,
scenario resilient technology
Appraise
(2009-11)
EFW project
Select
(2012-13)
Define
(2014-16)
Execute
(2017 +)
WG Phase 1Contract
shaping
WG demo
project
• Commissioned a 1.5 MWe demonstration project
• Joint investment with Syntech Bioenergy
• Plant will incorporate syngas testing facility
• Commissioning March 2018 – followed by feedstock testing
© 2017 Energy Technologies Institute LLP - Subject to notes on page 1
Lessons Learned
8
• Important to understand the long term role of an innovation in the low carbon transition – is it
scenario resilient or only viable under a narrow range of circumstances?
• Short term opportunities for commercial deployment are also important!
• Funding for first-of-a-kind commercial demonstrators is difficult – public funding through Research
Councils, Catapults, ETI and Government departments (e.g. DfT ABDC project) is often vital
• A careful and considered approach to scale-up is needed
• A stepwise or programme approach to technology development is more likely to build confidence
and drive innovation
…. and the implications of Brexit
• Inherently uncertain – but the UK has it’s own climate change commitments to deliver
• Opportunities to develop technologies and inform policy still exist - particularly in areas where Brexit
will force a policy rethink
© 2017 Energy Technologies Institute LLP - Subject to notes on page 1
Thank you for listening – any questions?
10 years of Innovation
21st – 22nd November, County
Hall, London
ETI Publications and
‘Knowledge Zone’:
http://www.eti.co.uk/
9
© 2017 Energy Technologies Institute LLP - Subject to notes on page 1
For more information about
the ETI visit www.eti.co.uk
For the latest ETI news and
announcements email
The ETI can also be
followed on Twitter
@the_ETI
Registered Office
Energy Technologies Institute
Holywell Building
Holywell Park
Loughborough
LE11 3UZ
For all general enquiries
telephone the ETI on 01509
202020.
Amec Foster Wheeler Connected excellence in all we do
Brexit: How will it impact the development of environmental legislation
Dr Stephen Wise
Waste Sector Director
5th July 2017
34
Specialist skills in environment
and infrastructure including
pharmaceuticals,
bio-processing, industrial,
water, transportation
and government
What we doEnvironment & Infrastructure
Markets
► Oil & Gas
► Clean Energy
► Environment & Infrastructure
► Mining
Offerings
► Consultancy
► Engineering
► Project management
► Project delivery
► Ongoing asset support
► Specialised power equipment
• General Election June 2017
• Added confusion to the Brexit process
• Will change stance from a hard to soft
Brexit?
• Will ‘red lines’ remain
• Brexit negotiations have started…
• What is our strategy
• What is the intended outcome
35
Brexit: Impact on environmental legislationTick tock, tick tock
Devolved Government for Scotland and
Wales
36
Brexit: Impact on environmental legislationDevolved government
• Strong central Government support
• Zero Waste Scotland
• Strong environmental legislation
• Stringent targets for recycling, recovery
and disposal
• Landfill bans for some wastes e.g. food
• Target both municipal and commercial
waste
• Circular Economy global leader
37
Brexit: Impact on environmental legislationDevolved government - Scotland
• Environment Wales Act 2016
• Sustainable management of natural
resources
• Climate change
• Charges for carrier bags
• Collection and disposal of waste
• Fisheries for shellfish and marine
licensing
• Flood & Coastal Erosion Committee and
land drainage
• 3rd highest rate for recycling globally!!
38
Brexit: Impact on environmental legislationDevolved government - Wales
• Business, Energy and Industrial Strategy
• Green Paper Jan 2017
• Innovate UK – significant funding being
provided e.g. £15m for manufacturing and
materials
• DEFRA
• No clear policy / backwater
• Stagnant recycling levels
• Voluntary agreements
• Energy generation not clear going
forward
39
Brexit: Impact on environmental legislationDevolved government - England
• The Repeal Bill
• Transfer of European legislation from last
40 years into new UK law
• Environmental, waste and recycling
legislation will transfer across
• Circular Economy package
• Will it be finished
• Will it be adopted
• Will it be transferred
40
Brexit: Impact on environmental legislationWhat will be in and what will be out
• The government is to end an
arrangement that allows other countries
to fish in UK waters, it has been
announced.
• Common Agricultural Policy
• Could there be impacts on this with
respect to food / commercial crops / GM
• Still significant unknowns…
41
Brexit: Impact on environmental legislationWhat will be in and what will be out
• Scotland and Wales have already taken
strong steps forward with environmental
legislation
• England has not moved and there is a
very clear Policy vacuum
• Existing legislation will be at least the
minimum we have…
42
Brexit: Impact on environmental legislationIn conclusion…
Thanks for listening
43
Dr Stephen Wise
Waste Sector Director – Environment & Infrastructure
QUESTIONS?
5 July 2017
• Dr Dimitris Charalampopoulos, Associate Professor in Food Biotechnology,
FoodWasteNet
• Sue Nelson, CEO, Breakthrough Funding
• Dr Stephen Wise, Associate Director, Environment & Infrastructure, Amec
Foster Wheeler
Food Waste: Are systems and
processes in place to effectively
manage green waste?
Deriving Increased Value from Food Waste & Co-
products
Dimitris Charalampopoulos
University of Reading
FoodWasteNet Director
www.foodwastenet.org
What is FoodWasteNet?• An active community of industrial practitioners and academic scientists dedicated
to creating economic value from pre-consumer food processing waste and by-products.
• One of 13 Networks in Industrial Biotechnology & Bioenergy, funded by BBSRC
• The Network runs for 5 years (2014-2019)
Food waste throughout the supply chain
Counting the cost of food waste: EU food waste prevention, House of Lords, European Union Committee, 2014
Why use food waste?
• It is a large potential feedstock for manufacture of higher value products
(3 Mt of food processing waste is produced each year in the UK)
• Reduce waste further
• Gain better economic value from waste and by-streams
• Opportunity to build the bio-based economy
• Develop alternatives to oil-derived chemicals e.g. bio-plastics, platform
chemicals, speciality chemicals
Percentage of food wastes and by-products in
different processes
AWARENET 2004, Agro-Food Wastes Minimisation and Reduction Network
Examples of Food Processing Waste
Vegetable trimmings,
pulps, out of spec
material
Fruit peels, pulps, out of spec
material
Starch based waste
(segregated or mixed)
Spent grains, vegetable oilcakes
Conceptual valorisation scheme
Target Products
Natural colours
BiopolymersBioactive compounds Flavours
BiofuelsChemicals
Case Study 1
Converting waste bread from sandwich industry to bioethanol
Industrial partner: University of Bath and Greencore Prepared Foods (sandwich
producer)
Background: 12.9 % of bread used in sandwich making is wasted and sent to AD (at cost
of £65 per ton) or diverted to low value animal feed
Project aim: Explore potential of bread waste as biofuel – to reduce waste management
costs and derive a higher value products.
Outcomes: Pilot study showed that bread waste could be successfully converted to
bioethanol and that the protein enriched residue could be a candidate for high value animal
feed
Case Study 2
Deriving value from pea-vine waste
Industrial partner: University of Nottingham and Green Pea Company
Project aim: Extract nutritionally-rich chemicals from inside chloroplasts in the cells of waste
pea vine plants
Outcomes: Useful nutrients can be extracted from chlorophyll in fresh pea vine waste:
particularly β-carotene (pro-vitamin A).
It is estimated that 30 million people in developing countries could receive their required
nutrient intake of vitamin A for a whole year if all the pea vine waste in the UK was processed
and the β-carotene extracted from individual cells.
Case Study 3
Exploring potential of rapeseed meal
Industrial partners: Glyndwr University, Larchwood Foods Ltd & Croda International
Project aim: Evaluate the how proteins in rapeseed meal could be extracted, enhanced
and used as foaming and emulsifying agents in personal care and cosmetic formulations
Outcomes: Proteins from cold-pressed rapeseed meal were found to be good
emulsifiers and could stabilise oil-in-water emulsions but had poor foaming properties.
Further treatment of the proteins yielded surfactants that were shown to be very effective
at reducing surface tension and able to form stable foams.
The materials show potential for use in personal care and cosmetic formulations.
REMAC- “Reformulation via Advanced
Cellulose Materials for Reduced Sugar, Fat
and Increased Fibre”, 2016-2019
Extraction of cellulose nano-fibres from vegetable
by-products (sugar beet, carrots)
Cosmetics, resins
Paints, coatings
“Development of novel value chain from cocoa pod
husks in Indonesia: Technological, environmental and
socio-economic challenges of a value chain”,
2017-2019
BBSRC Global Challenges Research Fund (GCRF)
Indonesian Agency for Agricultural Research and Development
• World’s 3rd largest cocoa producer
• Approx. 400,000 tonnes pa
• Low farming productivities and profitability
• Cocoa husks currently left on cocoa plantations
Address technological, environmental, economic and societal
challenges of developing a novel value chain for cocoa pod
husks
Key bottlenecks:
- Need to demonstrate process viability at scale
- Need to strengthen cross-links between stakeholders across the supply
chain including: food producers, chemical and industrial biotechnology
manufacturers, end users and consumers
- Investment costs
- Development of suitable business models
HOW TECH IS TACKLING FOOD WASTE
Sue Nelson
THE FOOD TECH LANDSCAPE
FOOD MARKETING PLATFORMS
FOOD COMMUNITIES
FREE-FROM PRODUCTION
CLEAN FOOD PRODUCTION
AGRI FOOD DEVELOPMENT
FOOD ANALYTICS
FOOD RESCUE AND FOOD
WASTE
FOOD TRANSPORTATION
ONLINE FOOD ORDERING AND
DELIVERY
COMMUNITY FOOD WASTE
FOOD RESCUE
HOW TECH IS TACKLING FOOD WASTE
Sue Nelson
Amec Foster Wheeler Connected excellence in all we do
Food waste: Are effective systems and processes in place?
Dr Stephen Wise
Waste Sector Director
5th July 2017
72
Specialist skills in environment
and infrastructure including
pharmaceuticals,
bio-processing, industrial,
water, transportation
and government
What we doEnvironment & Infrastructure
Markets
► Oil & Gas
► Clean Energy
► Environment & Infrastructure
► Mining
Offerings
► Consultancy
► Engineering
► Project management
► Project delivery
► Ongoing asset support
► Specialised power equipment
• Figures for the UK 2015
• 4.4 million tonnes of food waste
• £13 billion in value
• £470 per household
• 19 million tonnes of CO2
73
Food waste…The scale of the challenge
74
Food waste…The scale of the challenge
• Part of devolved matters to the Scottish
and Welsh Governments
75
Food waste…Current legislation
76
Food waste…Current legislation
England Scotland Wales
Government
support
Clear Policy
in place
Landfill bans
in place
Mandatory
collections
Recycling
levels
• Scotland and Wales have very clear policies
in place for the collection and treatment of
food waste
• Wales – mandatory food waste collection
• Scotland - >5kg food waste
• Investment in collection and treatment
infrastructure
• Anaerobic Digestion
• Targeting both municipal and commercial
food waste
• Increased quantities of food waste collected
77
Food waste…Implications…clear policy/clear benefit
• England
• No clear direction for the collection and
treatment of food waste over the past 10 years
• Landfill Allowance Trading Scheme (LATS) to
discourage Biodegradable Municipal Waste
(BMW) from going to landfill – tradable permit
scheme
• PFI / PPP schemes e.g. Mechanical &
Biological Treatment (MBT)
• LATS removed!!! No incentive
• Now in at least two cases food waste
collection schemes have been introduced
78
Food waste…Implications…muddled thinking
• Education and communication is a ley part of
developing and implementing a successful
food waste collection scheme
• Challenge with cuts to funding BUT cutting
communication short term gain – long term
implications
79
Food waste…Collection schemes
• Needs to be part of a well thought and
integrated collection system
• For example…do you collect food waste with
/ without garden waste
• Collection impacts treatment
• IVC / AD
80
Food waste…Collection schemes
• Full economics need to be considered
not just in isolation
• Haulage
• Reduced collection frequency
• Different collection rounds
• Collection vehicles
• Tipping costs (gatefee)
• Potential for return revenue e.g. energy
(electricity/gas)
• Commercial collections
81
Food waste…Collection schemes
• England
• No central direction
• Local decision for waste collection and
disposal authorities
• Scotland
• Yes, strong and effective process in place
• Wales
• Yes, strong and effective process in place
82
Brexit: Impact on environmental legislationIn conclusion…
Thanks for listening
83
Dr Stephen Wise
Waste Sector Director – Environment & Infrastructure
QUESTIONS?
5 July 2017
• Sue Nelson, CEO, Breakthrough Funding
• Paul Henderson, Head of Bioeconomy Strategy, BEIS
• Tom Robinson, Founder/Managing Director, Adaptavate
Policy & Regulation
Vision and Objectives
The UK Bioeconomy
Growing the UK bioeconomy
Paul Henderson
Department for Business, Energy and Industrial Strategy
Deliver and ambitious Industrial Strategy
Maximise investment opportunities and
bolster UK interests
Promote competitive markets and responsible
business practices
Ensure the UK has a reliable, low cost and clean energy system
UK policy landscape
Existing policies covering:
Energy
Decarbonisation
Environment
Waste
Industrial Strategy Green Paper
Bioeconomy Strategy
What does the bioeconomy represent?We surveyed a panel of
1,000 members of the
public…
…1 in 5 people have heard of the term
“bioeconomy” – to some
extent
10%
8%
11%
11%
11%
13%
17%
20%
Don't know
Creating new high skilled jobs
Making farming more productive
Being at the forefront of scientific advancements
Greater investment in clean energy
Making best use of our waste products
Having a secure and resilient food supply
Reducing our reliance on fossil fuels & products
% viewing each item as the most important
When presented with a range of possible benefits from the bioeconomy, and pressed on which single area is most important to the UK, participants highlighted the following:
3% 5% 51% 42%
Importance of the bioeconomy amongst those who know a lot or little about it
Don't know Not at all important Not very important Fairly important Very important
Size of the bioeconomy
0%
2%
4%
6%
8%
10%
12%
0
50
100
150
200
250
300
350
Germany France Italy Spain UK
€b
illi
on
Production potential Share of national production
Intesa Sanpaolo Research Department presented their third
report dedicated to bioeconomy on 24th March, showing the
bioeconomy is worth €1.22 trillion in five EU countries:
Bioeconomy products“The UK chemical industry currently has sales of
over £60bn per annum… around £6bn of this
might be replaced with renewable chemicals
produced from waste materials.”
House of Lords Select Committee (2014):
Waste or resource? Stimulating a bioeconomy
Ref: InnProBio
“Strong efforts are needed to address the current
imbalance between material and energy uses
of industrial residues where more significant
potential for cascading exists.”
EC (2016): Study on the optimised cascading use of wood
Evidencing a UK strategy
Industry Leadership
AFTC
CGP
IBLFMMIC
SBLC
Multi-disciplinary project team
BEIS
I-UK
BBSRC
KTN
Barriers and opportunities
Scale-up challenges (SMEs)
Lack of funding for translational research
Costly scale-up and demonstrator facilities
Others e.g. regulatory / licencing costs
Skills needs
Technical / entrepreneurial / business
Recruitment: Brexit & freedom of movement
Interdisciplinary training
Consumer acceptance
Of technology – GM and synthetic biology
Little demand for bio-based products
Low awareness of benefits
Attracting investors
Low return over long timescales
Do not understand sector
New technologies seen as high risk
Barriers raised by stakeholders include:
Barriers and opportunities
Increased sustainability
Circular economy
Low carbon future
Bio-based products
Bio-based packaging
High value chemicals
New products / functionality
Place-based solutions
Bioeconomy clusters
Build on existing expertise
Use local resources
Best use of resources
Food waste
Low-grade timber
Marine bio-resources
Opportunities outlined by stakeholders include:
Cross-cutting considerations
Value creation
Skills
Energy production
Land use
Cross-sector
Increased awareness
Policy & Regulations
What’s next?
Current Opportunities Ambitious Growth
Sector Deal
ISCF
CfE Response
Strategy
Delivery
£440bn GVA in 10yrs
A Clear Way Forward
Further engagement across public and private sector
A bioeconomy strategy that works for all parts of the UK
Thank You
Paul Henderson
Head of Bioeconomy Strategy
Department for Business, Energy and
Industrial Strategy
Bio Based Innovation
Expo - NEC
Wednesday 28th June 2017
Thomas Robinson
Founder/CEO
+44 7969 388684
www.adaptavate.com
What’s to come?
• Background of Adaptavate• What problem do we solve?
• How do we solve it?
• How have we used public and private funding to get where we are?
• What next?
Construction
In 2012, The UK produced
200 Mn Tonnes
of waste.
https://www.gov.uk
Resource security?
Improve energy efficiency
14 litres of moisture
Condensation
Mould
Air tight buildings
Creative
Commons
5.4 MnAsthmatics
in UK
90%of our time
Indoors
Higher performing materials.
- Moisture buffering
- Thermal
We can grow materials of the future =
renewable.
Totally compostable – Nutrient
NOT Pollutant.
+
Build Centre, Shore St, London
‘My dog has
ideas’
But how do we
take them to
market ready
impactful
innovations?
How to go from idea to IMPACT?
https://tapmiblogs.wordpress.com/2011/05/12/startups-in-india-their-funding/ https://www.shellypalmer.com/2013/05/startup-depression/
• Conservative industry resistant to
change
• Product regulation and certification
• Heavy industrial process to reach scale
• New supply chain with new flows of
materials upstream
Friends, family and fools?
Competitions and accelerators
Accelerators in UK
205
163
11
Incubators
Accelerators
Pre-accelerators
http://startups.co.uk/uks-incubator-and-accelerator-network-booms/
(Seed stage)
• Access to seed funding
• Access to mentorship and tutorials
• Network of commercial partners/research institutions/other start ups
• First customers
• Credibility
Research Councils
• Scientific validation of your concept.
• Proof of concept
• Normally non-cash.
• Medium waiting period
Work with:
R & D tax credits: 33.35% of eligible spend
Raising capital to grow/develop
Up to £150 k investment
50% CGT relief
Up to £5 mn investment
30% CGT relief
Innovate UK and Catapult Centres
• Great facilities with
cross-industry
knowledge.
• Access to partners
and potential
customers/investors
• Add credibility to
proposition• Keep team lean
What next?
• Increase productivity
• Exportable goods
• Uncertainty
What support for companies such
as Adaptavate ready for scale
up?
What are we looking for?
• Partners in UK an EU• Manufacturing partners
• Research institutions
• Investors seeking a scale up
• Technical manager – become an Adaptavator!
Bio Based Innovation
Expo - NEC
Wednesday 28th June 2017
Thomas Robinson
Founder/CEO
+44 7969 388684
www.adaptavate.com
QUESTIONS?
5 July 2017
Networking break –
conference resumes
at 12.40
BIO TECHNOLOGY
SHOWCASES• Myriam Moeyersons, Marketing Manager Biopolymer, Kaneka Belgium NV
• Dr Gareth Roberts, Head of Business Development, Cambond
• Tom Robinson, Founder/Managing Director, Adaptavate
• Elspeth Bartlett, Head of Communications, Biovale
• Dr Mateuz Kmet, Head of Business Development, Acies Bio
• Henri Colens, Public Affairs Manager, Braskem
||Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH 12507/07/2017
Kaneka Biodegradable
Polymer PHBH™
Myriam Moeyersons
Marketing Manager Biopolymer
||Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH 12607/07/2017
1. KANEKA Company Profile
2. General Information of PHBH
3. Examples of PHBH Applications
||
KANEKA
CORPORATION
Kaneka Corporation
President
Mamoru Kadokura
COMPANY NAME
ESTABLISHED
01 September 1949
9.376(incl. consolidated subsidiaries)
EMPLOYEES
HEAD OFFICE
Japan, Osaka & Tokyo
BUSINESS OPERATIONS
Europe (head quarters in Belgium KANEKA BELGIUM),
America, Asia (outside of Japan) and Oceania
BUSINESS
FIELDS
Chemicals, Functional & Expandable
Plastics, Foodstuffs, Life Science,
Electronic Products, Synthetic Fibers
NET SALES
555 billions of Yen
CORPORATE
OVERVIEW
DATA (as of 31 March 2016)
Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH 307/07/2017
= 4,3 billions €
||Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH 12807/07/2017
Kaneka’s chemistry originated in our
fermentation and macromolecular
technologies.
By developing these two core
technologies, we have created
various unique technologies.
Kaneka’s chemistry started from two technologies
||Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH 12907/07/2017
1. KANEKA Company Profile
2. General Information of PHBH
3. Examples of PHBH Applications
||
Life Cycle of Kaneka Biodegradable Polymer PHBH™
Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH 13007/07/2017
Sea Water
compliant with
ASTM D7081
PHBH
PHBH
copolymer of 3-hydroxybutyrate
and 3-hydroxyhexanoate
||
Kaneka Biodegradable Polymer PHBH™
Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH 13107/07/2017
copolymer of 3-hydroxybutyrate and 3-hydroxyhexanoate
Average Mw: 500,000 - 600,000
Composition ratio of rigid grade: 3HB/3HH = 94/6, (X131A)
Composition ratio of semi-rigid grade: 3HB/3HH= 89/11, (X151A)
||Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH 13207/07/2017
Production of PHBH2011: Start production (capacity 1.000 MT/year)
Pilot plant
Kaneka Biodegradable Polymer
PHBH™
||Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH 13307/07/2017
1. KANEKA Company Profile
2. General Information of PHBH
3. Examples of Applications
||13407/07/2017Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH
Anaerobic Waste Management
4C4H6O2 + 6H2O 9CH4 + 7CO2
Organic waste in AD waste bags are put directly into
digester
Project performed at Nantan-city, Kyoto, Japan
Generation of methane
Formulation:
• Kaneka Biodegradable Polymer PHBH™
• Other biodegradable resins
• Additives
||Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH 13507/07/2017
Biodegradability - Aerobic & Anaerobic
Aerobic condition
Anaerobic condition
During both conditions PHBH biodegrades
very well
||
Recovery from denudation, a project performed together with Shizuoka Prefecture,
Fishery Development Division and Suzuyo Shoji Co., Ltd
19/Feb/2014
nursery seaweeds bound on PHBH plate.
Result: seaweeds on PHBH plates grew well and roots spread on the rocks.
PHBH plates will degrade and disappear.
26/Aug/2014 27/Oct/2014
13607/07/2017Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH
Marine Environment
||Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH 13707/07/2017
Biodegradability – Marine
Sample: 100 µm thickness PHBH film
Condition: 27˚C, aerobic
Sea water: from Osaka bay, Japan
Sea water
Result: PHBH biodegrades in the sea water
CO2 absorber
・・・Ca(OH)2
Film &
stirrer
C4H6O2+ 4.5 O2 4 CO2+ 3 H2O
Tests performed via measurements of biological oxygen demand
||Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH 13807/07/2017
Biodegradable Applications
Marine:
Aquaculture
Nature restoration
Denitrification RAS
Waste Management:
garbage bags
Horti & AgriCulture:
Mulch film
Plant pots
Plant Clips
Food:
Packaging
Coffee Capsules
Disposable tableware
Fiber
& non-woven
fabrics
||Myriam Moeyersons | Presentation Kaneka Biodegradable Polymer PHBH 13907/07/2017
Thank Youfor your attention
We look forward to meet you at our booth L 901
Contact details: [email protected]
GREEN TECHNOLOGY FOR GREEN PRODUCTS
CONFIDENTIAL
Wood Panel Industry – Global Scale and Problems
Oil Based Toxic Urea/Phenol/Formaldehyde
Adhesives
Plywood, OSB, MDF for construction, furniture etc. ETC
CONFIDENTIAL
Sustainable
Environment
Low Carbon
CAMBOND MISSION
神农科技
CAMBOND INNOVATION
Proprietarytechnology
Biomass basedLow carbon
( <60% of UF resin)
Lowtoxicity
Environmentallyfriendly process
Meets industrialstandards
Recyclable
Green Board
Food grade feedstock.By-products from:
Bioethanol production Algae farming
Sugar beet Pineapple
SUPPLY CHAIN
ALGAE
STRAW
REED
DDGS
CambondBIO-COMPOSITES BIOPLASTIC
PRODUCTS
MOULDED PRODUCTS
WOODPANELS
PRODUCTS FOR GREENER BUILDING
Standard wood panels (meet E0, J****, CARB2)
New generation straw panels (equivalent MDF, BSEN P4-P1 )
CAMBOND AS A GREEN BUILDING PARTNER
Cambond panels have reduced (50% carbon footprint).
Cambond panels can be used on almost all buildings with immediate effect on carbon footprint
Cambond panels meet quality criteria at similar price
World beating proprietary technology
Cambond panels easily integrated into existing work practices.
Research and development in UK shows our resin can bind straw and other biomass fibres.
We can produce moulded and extruded products.
Biomass can replace plastic in a manufacturing process.
Biomass based products can be carbon –ve!!!
NEW GENERATION – CAMBOND BIOPLASTIC PRODUCTS
CONFIDENTIAL
CAMBOND BIOPLASTICS - CONSUMER’S PRODUCTS
CONFIDENTIAL
ECO-PALLETS
CONFIDENTIAL
New generation straw pallets (ISPM 15 COMPLIANT)
Light weightReplacement of Wood PalletsAlternative to Plastic PalletsCost-Effective Space saving for delivery
INTERESTED?
STAND K903
CAMBOND LTD
Bio Based Innovation
Expo - NEC
Wednesday 28th June 2017
Thomas Robinson
Founder/CEO
+44 7969 388684
www.adaptavate.com
Let’s grow the materials of the future
Construction
In 2012, The UK produced
200 Mn Tonnes
of waste.
https://www.gov.uk
£180 - 260/tonne disposal
Resource security?
Global Gypsum Producer Price Index = 10 year high
Citation: U.S. Bureau of Labor Statistics, Producer Price Index by Industry: Gypsum Product Manufacturing: Gypsum Building Materials [PCU3274203274201],retrieved from FRED, Federal Reserve Bank of St. Louis; https://fred.stlouisfed.org/series/PCU3274203274201, July 3, 2017.
Improve energy efficiency
14 litres of moisture
Condensation
Mould
Air tight buildings
Creative
Commons
5.4 MnAsthmatics
in UK
90%of our time
Indoors
Higher performing materials.
- Moisture buffering
- Thermal
We can grow materials of the future =
renewable.
Totally compostable – Nutrient
NOT Pollutant.
+
Absorb pollutants from the air
Build Centre, Shore St, London
Rob Townson
Partitioning sub-contractor
“Breathaboard is
just like the
conventional boards
to install.”
Tom Lacey, Director, Barr Gazettas.
“We were drawn to Adaptavate because
the products are low carbon, recyclable
& have the potential to have a real
positive impact on staff Health &
Wellbeing. The products were easy to
use and we were able to achieve a
good, professional level of finish."
Richard Griffiths, Head of Commercial Policy,
UKGBC
“We aimed to demonstrate the highest standards of
sustainability and showcase innovation in the
sector. Adaptavate’s Breathaboard and
Breathaplasta helped us achieve both of these
aims with their all-natural, low carbon alternative to
the standard plaster products”
Competitors ofPlasterboard
Breathaboard
(predicted)Fermacell EBB Board ClayTec Wood Wool
Price, per m2 (RRP) £4.00 £7.50 £9.20 £16.98 £34.00 £10.50
Air Quality
Breathability. VOCs. Toxicity
.
Poor Excellent Poor Good Good OK
Ease of Installation Good Excellent OK Poor OK Good
Physical Characteristics
Thermal & Acoustic
Installation. Robustness.
Good * Good Good Poor OK Excellent
Environmental Benefits
Longevity of resource.
Landfill pressure.
Poor Excellent OK Excellent Good OK
Circularity
Renewable material
Biodegradability.
Poor Excellent OK Good OK OK
Market opportunity
$18.07 Bn
2016$23.85 Bn
2021 By: marketsandmarkets.comPublishing Date: January 2017
European market held by 4 main companies
All completely tied to gypsum as feedstock
~10% of this market is ‘specialist’ boards
~60% of this market is insulation boards
Our initial focus in UK
Type of
property
segment
Number of
houses in
UK (Million)
Replacement
rate
Total annual
market
(boards)
Total
Addressable
UK market
Aimed %
of
market
Total annual
market share
Eco/heritage
market1.2 15 years 12 million £90 mn
5%£4.5 mn
Solid wall
properties
(private owned)
1.79 15 years 17.9 million £131 mn 1% £1.3 mn
Housing
Association0.2 5 years 6 million £45 mn 0.3% £140k
Create the value chains to support the scalable introduction of bio materials to the construction
market.
Raw materials and bio
feedstock
Scalable production
process
Downstream demand
Next 6-9 months
• Work with key partners
to validate continuous
industrial process
• Continue to develop
relationships across
European value chain
Next 5 years
Year 1: Build and operate factory 1
Year 2: Build European market
Year 3–5: License IP and production plant and know how
to scale into European markets
Leader in continuous manufacturing of fibrous
materials to create products for the mainstream construction industry.
What are we looking for?
• Partners in UK an EU• Manufacturing partners
• Research institutions
• Investors seeking a scale up
• Technical manager – become an Adaptavator!
Bio Based Innovation
Expo - NEC
Wednesday 28th June 2017
Thomas Robinson
Founder/CEO
+44 7969 388684
www.adaptavate.com
||
Elspeth Bartlett
insert
||
Dr Mateuz Kmet
insert
||
Henri Colens
insert
QUESTIONS?
5 July 2017
||
Chair: Dr Paul Hudman, Business Development Manager,
Industrial Biotechnology Innovation Centre (IBioIC)
Panellists:• Juliet Burns, Communications & Marketing Manager, Biorenewables
Development Centre
• Dr Eve Bird, Head of Research & Innovation, Celtic Renewables
• Dr Michael Watson, Research Scientist, CelluComp
• Dr Peter Hammond, Chief Technology Officer, CCm Research
Biomass to Chemicals
Biomass to Chemicals
Dr Paul Hudman,
The Industrial Biotechnology
Innovation Centre
Birmingham NEC, 5th
July
Industrial biotechnology (IB) is the use of
biological resources (including plant, algae,
marine life, fungi and micro-organisms) for
producing and processing of materials,
chemicals and energy
• Focus areas:
• Forestry
• Industrial/ Commercial
Waste incCO2
• Marine
• Synthetic Biology
What is a Biorefinery?
Resource Process Products
184
Biorefineries for the futureJuliet Burns, 5 July
185
About the BDC
The BDC is an open-access R&D centre
working at the interface between academia and
industry to develop, scale-up and help
commercialise bio-based products and processes.
Our vision is a world where the
economy is a bioeconomy.
186
What makes us different?
With both biologists and chemists, the BDC team offers a unique combination of multi-disciplinary expertise coupled with state-of-the-art pilot-scale processing capabilities in one coordinated centre.
… and access to academic researchers
across the University of York
187
Biorefining value pyramid
Value (£)
Volume (t)
Chemicals
Materials
Fuels
Energy
188
New crops for bio-based lubricants
With thanks to our funders:
Commercial feasibility assessment for a new type of oilseed rape to provide a greener
alternative to the mineral-based oils
currently used industrially
189
Pharmaceuticals from food by-products
Project partners:Conversion of starchy and
lignocellulosic waste into antibiotics
190
Batteries from biomass
EU collaboration to prove feasibility of
using starch in energy storage and
green catalysis
This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No. 686163.
This material reflects the author's view and the Commission is not responsible for any use that may be made of the information it contains.
H2020: GA n°686163
191
Food waste valorisation in the UK
Uses for beer, whiskey and fish
by-products
Resource mapping study
Waste valorisation in the dairy sector
Opportunities for fresh produce,
bakery and beverage by-
products
192
Simplifying biorefining R&D across the UK
Work with us
We work with organisations large and small on diverse projects to help de-risk the bio-based innovation process.
Courtauld signatory
Voluntary agreement to reduce the environmental impact of the UK food chain; signatories represent 93% of the 2016 food retail market.
BioVale cluster
BioVale promotes Yorkshire and the Humber as a thriving centre of successful innovation for the UK bioeconomy.
Member of BioPilotsUK
An alliance of established open-access biorefining centres collaborating to support the UK bioeconomy.
With thanks to our funders
193
www.biorenewables.org
||
Dr Eve Bird
insert
Bioinnovation Conference
Biomass to Chemicals
5th July 2017
Michael Watson
Company Background
Founded in 2005, CelluComp is a material science
company that produces sustainable materials from agri-
food by-products.
Development and production scale up of Curran® has been
part funded through the European Union Project
Headquarters and R&D – Burntisland, Fife, Scotland
Production Plant – Glenrothes, Fife, Scotland
Adding Value to Biomass
197
Low Value Bye Product or Waste Biomass
ProcessTransformation
Modification
Material (Chemical)With useful
properties that meets a need
Sugar beet
Chemical or Enzymatic
Extraction of components from
cell walls
Curran®
Waste Streams from Agri-Food are turnedinto high-valued additives
Personal Care
Home CarePaper/Packaging
Food
Coatings
CompositesConcrete
Oil
Curran® Market
Shear thinning
Stable viscosity from pH 2 - 12
Viscosity
Curran
HEC
5mm WFT putty withoutCurran® after 20 min @ 40ºC
Curran® promotes uniform through drying
5mm WFT putty withCurran® after 20 min @ 40ºC
Drying Behaviour
Scrub Resistance
Improved resistance to mud-cracking and micro-cracking
Film Cracking
Low Temperature Crack Resistance
Modified with Curran® Standard Formula
Curran® Production Facility
Small production facility built and in operation since 2015 allowing process optimisation and supply of Curran®
Next steps are scale-up to commercial scale demonstrator plant
CelluComp - Summary
• Biomass to highly effective multi-functional material Curran®
• Curran® is a member of materials known as Nano-Cellulose
• Applicable in a wide range of markets
Improve product properties AND
Reduce costs for customers
Nano-Cellulose Market
“The key players in the field of Cellulose
Nanoparticles are Blue Goose Bio refineries Inc,
Borregaard, Bowil Biotech, Cellucomp Ltd, Cocosong Food Industries, Colorado School Of
Mines, and Earthrise Nutritionals Llc.”
USDA estimate short term (by 2025) market of 34 million tonnes per Year (TAPPI 2014)
Rapid growth in production from 2013-15 1000% increase expected 500% + increase in capacity by 2017 (Biofuels Digest Oct 2014) (Market research reports- July 2015)
(Market research reports- July 2015)
1. Nano Cellulose is very big business opportunity
2. CelluComp is a leader within this category
3. Demand for the product is growing very quickly
||
Dr Peter Hammond
insert
QUESTIONS?
5 July 2017
||
Chairman’s summary and
concluding remarks
||
End of Conference