Design for Sustainability PDF

Summary

This document explores different aspects of design for sustainability, from the use of recycled materials to the application of innovative technologies. It touches on topics like the design of sustainable products, the role of water conservation in design, and the idea of a holistic approach to sustainability.

Full Transcript

Design for Sustainability
D4S has emerged, which in its broadest and most
inclusive meaning could be defined as

A design practice, education and research that, in
one way or another, contributes to sustainable
development
How to achieve sustainability
through design
PET bottles to Jeans
In an attempt to tackle waste,
Levi’s has created a new denim range which
Uses eight plastic bottles for each pair of jeans

Global bottled water consumption was more
than 29 litres / person / year

PET and poly propylene

Recycling rates were 29 % in US and 51% in
Europe at the time the project started

Design interventions
PET bottles to Jeans
Research and development - from the design to new
fibre-spinning techniques to sourcing waste plastic –
has gone into waste less line
Plastic bottles and food trays are collected from
municipal sites, cleaned, sorted, crushed into flakes and
made into polyester fibre
This is blended with cotton fibre, which is finally woven
with traditional cotton yarn to create the denim
The look and feel seems no different from traditional
denim, apart from the colour of the inside, which varies
according to the hue of the plastic used in the weave:
brown, green or clear.
PET bottles to Jeans
The company has reused more than 3.6 million
bottles and food trays for the 3,00,000 waste less
jeans and jackets produced for its 2013 collection,
bottles that would otherwise have ended in a
landfill or even burnt in incinerators
Vortex – spiralling movement of a
liquid
Lowest energy path
Water always try to travel in a vortex
Availability of clean water
Innovation – the vortex has the capacity to
dramatically increase efficiency in water
treatment, cutting costs while generating
local jobs
Technology platform of the vortex is inspired
by the observation of dirty water cleanses
itself as a river moves downstream
The continuous swirling motion forces air in
and out of the water, discouraging and
stimulating beneficial micro-organisms
Vortex - application
Vortex – Blue economy
Crystal clear ice
Vortex machine helps to generate crystal clear ice since,
water which includes air, dissolved in micron-size bubbles, is
free now
Air also acts as an insulator and requires more energy to
cool water into ice. Hence now the energy and time
required to make ice reduced.
Air free ice also cracks less readily
Ice rink
Since there is no air in ice, aerobic bacteria that typically
grow in ice like E.coli and Salmonella cannot survive
Vortex - application
Golf courses
0.3 million litres of water a day
To save water, surfactants are added to water so
that it penetrates faster into the lawn and less
evaporates.
If the water is treated by vortex machine, no
chemicals are needed, reducing water requirement
by 20 to 30 percent
Vortex - application
Removal of algae from stable water bodies
Including swimming pools, which otherwise use Cl

Treatment of salt water
Eliminates formation of bio film on membrane – reduces
membrane efficiency – leads to closure of desalination
plant’s reverse osmosis installation every fortnight to
chemically remove biofilms – increases maintenance
costs and reduces plant efficiency
Blue economy: 10 years- 100
innovations – 100 million jobs
Gunter Pauli
Blue economy business model will shift society from
scarcity to abundance “with what we have”, by tackling
issues that cause environmental and related problems
in new ways
It highlights potential benefits in connecting and
combining seemingly disparate environmental
problems with open-source scientific solutions based
on physical processes common in the natural world, to
create solutions that are both environmentally
beneficial and which have financial and wider social
benefits.
More examples
Coffee to mushroom farming
Cradle to cradle ink
Biomimetic approach design of systems
Cradle to cradle
100 % renewable energy use
Clean water output
Social responsibility positive impact on community
Material reutilisation recyclability / compostability
Material health impact on human and environment
Kluber lubricant service – S.A.T.E
Evolution of design process
What is green design?
Linear and cyclical design
Building design process
Transitional model
Green design
Exact point of time not known
Green design transcends mere descriptions of the
techniques that may be employed in shaping a
more sustainable existence on Earth
It must also incorporate the principles, processes,
and cycles of nature in a way that leads to a deeper
understanding of what makes a design successful
Green design
Designs of much of past four centuries have
assumed an almost inexhaustible supply of
resources
By applying laws of science, we can shape our
environment and provide the products demanded
by society both predictably and sustainably
 “The significant problems we face cannot be solved
at the same level of thinking we were at when we
created them” Einstein

https://www.youtube.com/watch?v=IJzd6Hxnmzw
Green design
Since the industrial revolution of the nineteenth
century, architects and engineers have been key
players (culprits?) in the war against nature.
Single-minded exploitation and subjugation of
nature was the norm during much of the twentieth
century and persists as a mainstay of design.
Technology has hastened the process.
Use of ACs in houses
Is green thinking new?
green thinking is not new at all.
In fact, our new way of thinking resembles an
understanding of and respect for nature found in
antiquity, as evidenced by the designs of native
peoples
Reestablishing the link between built form and the
environment will require a more complete
understanding of the science
Green design
A more complete understanding of the first
principles of science and a reexamination of the
“normal” process of conception and delivery in the
design and construction communities puts the
green designer in a position of strength.
Phosphate free product
simply replacing the solvent with a water-based
solution is often desirable
LCA
Link with local
The law of unintended consequences is ever ready
to raise its ugly head in design
There are numerous examples of building design
solutions touted as sustainable that fail to
recognize and respond to the specifics of local
climate.
Wind turbines in an area that does not generate
sufficient wind speeds throughout the year.
Holistic approach needed
design decisions on how we shape our
environment also include less tangible impacts on
the individual, society, and ecology that may not fit
neatly on a data spreadsheet.
Not necessarily cost-benefit ratio
LINEAR AND CYCLICAL DESIGN
The critical path from building conception to
completion has changed very little over the
thousands of years since humans began to shape
the environment to create shelter from the
elements
Engineers vs Architects
Strength / usefulness
Delight / beauty
 It was not until the industrial revolution that
boundaries between professions began to become
distinct, opening a path toward specialization
The industrial revolution brought the rise of
transportation and manufacturing infrastructure,
providing the ability to fabricate components off-
site and assemble on-site.
Design
Merriam-Webster Collegiate Dictionary defines
design as “to create, fashion, execute, or construct
according to plan” and “to conceive and plan out in
the mind.”
Design process
The actual view of the process of design, however,
varies substantially both within the professions and
between design disciplines.
Some view the process as purely direct, sequential,
and linear, following a prescribed set of activities
that will lead to a final solution.
This stepwise approach is often referred to as the
waterfall model, drawing on the analogy of water
flowing continuously through the phases of design.
Building design process
The process of design and delivery of buildings in
particular, from conception to completion, has
generally followed a linear or stepwise model in
which distinct phases guide the design from
definition of need or problem statement, followed
by drawings through technical evolution,
construction, and final completion.
Linear Design Model
Steps in Linear model
Program or Problem Statement – need, why
Skeletal Form or Schematic – support structure,
design to meet the objectives
Systems Development – development of internal
systems
Technical Detailing and
Documentation/Implementation
Transitional model
Linear model is unchanged for decades
The means for ensuring sustainability has been
achieved using accountability point systems, such
those in the Leadership in Energy and
Environmental Design (LEED)
Such documentation and recognition of
“greenness” has emerged to encourage design and
construction professionals to create projects with
an eye toward environmental quality
Goal as a part of design
Transitional model
Designs now undergo a series of integration steps,
which have been articulated by Mendler et al
Project description
Team building
Education and goal setting
Site evaluation
Baseline analysis
Design concept
Design optimization
Documentation and specifiations
Building and construction
Post occupancy
Transitional green design model
Key difference between 2 models
Transitional model - each step includes feedback to
the preceding steps

A key difference, however, is the extent of
integration of goals into the design process.
Mendler et al. identify global goals
that must be part of a green design
Waste nothing (a “less is more” approach; reuse,
avoiding specification of scarce materials).
Adapt to the place (indigenous strategies; diversity, form
fit to function).
Use “free” resources (renewable energy, renewable
materials, locally abundant resources).
Optimize rather than maximize (synergies, less reliance
on active, mechanical systems)
Create a livable environment (protect sensitive
ecosystems, actively restore damaged habitats, look for
pedestrian-friendly and mixed-use design options; avoid
toxic materials).
In a nutshell.
The difference between the stepwise and transitional
models is that the former is based on monetary costs,
scheduling constraints, and quality; whereas the latter
expands to integrate human health, safety, and
comfort as well as ecological considerations
the transitional model requires that even more scrutiny
be given to costs, scheduling, and quality, so every step
is reviewed in light of the preceding and subsequent
steps
The dynamic nature of the model means that more
variables are introduced with each step
LEED
The LEED Green Building Rating System was
conceived and implemented by the United States
Green Building Council (USGBC) to define and
measure the sustainability of “green buildings.”
The USGBC, created in 1993, formed a diverse
committee representing expertise in architecture,
engineering, real estate, environment, and law
focused on the creation of a benchmark for
measuring building performance.
LEED benefits
One of the important by-products of the
introduction of this system framework is the
increased collaboration between design and
construction professionals united by common tools,
principles, and the desire to achieve high-
performance buildings
LEED benefits
Benefits of the program now extend well beyond
the building community, as both the public and
private sectors recognize the benefits of sustainable
design and now in many cases require the
incorporation of these design principles, providing
direct and indirect financial incentives and
recognition.
LEED benefits
Another ancillary benefit of the rating system is
that it has created markets for green materials.
For example, points are given for reusing building
materials, such as old ceiling tiles, which had
previously found their way to landfills.
Green roof
A green roof (also known as a vegetated roof) is an
area of roof surface that is covered with living plant
matter
Benefits
Preventing heat gain (also known as the urban heat
island effect)
Evaporation creates a cooling effect on the building
Prefiltering rain water for later use
Buffering rain water to prevent rapid site run-off
Pleasing aesthetics
Increasing the roof lifetime
The Synthovation/ Regenerative
Model
Design is moving toward more sustainable
solutions by increasing the role of teamwork to find
synergies through synthesis and innovations
synthovation: synthesis being the merging or
integration of two or more elements, resulting in a
new creation, and innovation being the
introduction of something new—an idea, method,
or device
Innovation
change that creates a new dimension of
performance
the capability of continuously realizing a desired
future state
The Synthovation / Regenerative
Model
Emerging collaboration software tools are
creating the potential for powerful synthesis and
integration across technical expertise that has
historically remained segregated until much later in
the life of a project’s development.
This migration of technical input to earlier phases
of the design process holds the opportunity not
only for more complete synthesis but also the
promise of innovation in the way we conceive and
shape the built environment.
(a) Synthovation model adapted from the
nautilus shell; (b) nautilus shell cross section
nautilus shell cross section
The nautilus shell and sunflower seed patterns provide
useful analogies when describing this new model that
bridges concept to completion, with multiple
interlocking spirals representing the continuous
iterative process and integration of multiple dimensions
of technical expertise
The spiral pattern is repeated in nature in many
variations
from the rotation of plant stalks to provide leaves with
optimal exposure to sunlight by never occupying the same
position twice, to the spiral growth pattern of a seashell,
continuously expanding and maintaining optimal structural
strength
Synthovation
The design process that follows this spiral approach
is preferable to the current “loops,” which
represent feedback.
Often, however, a synergistic and innovative design
never goes backward.
In fact, better and, frequently, more cost-effective
features are being integrated into the project
continuously.
Secondary costs
Integrated approach
Design software is becoming increasingly robust.
Design teams can rapidly develop prototype
alternatives early in the process and continue to test
development as solutions emerge and take form.
And as we gather more data and test these models, our
uncertainties will continue to decrease.
Of course, we will never be completely certain about
outcomes, in light of the myriad influences and
variables.
However, the integrated approach is much better than
the brute force of a single design strategy, in which we
can only hope that there will be no unpleasant
surprises down the road (e.g., material and system
incompatibilities, unexpected operational costs, change
orders, retrofits).
Synthovation - collaboration
Synthovation - collaboration
Continuous improvement calls for sound science
For example, a more complete picture of energy
consumption is gained by models able to look both
upstream to manufacturing and transport to
account for embodied energy, as well as
downstream to test the digital prototype against a
range of environmental conditions, not simply a
static condition derived from the averages for a
particular site.
THE NECESSITY FOR SYNTHESIS-INTEGRATED
INNOVATION IN SUSTAINABLE DESIGN

Daniel Pink in his book A Whole New Mind
He identifies six essential right-brain aptitudes
necessary for the “whole new mind” that this new
era will demand: (1) design, (2) story, (3) symphony,
(4) empathy, (5) play, and (6) meaning.
MODELS FROM NATURE OF
INTEGRATED SYSTEMS DESIGN
Human subtlety will never devise an invention more
beautiful, more simple or more direct than does
Nature, because in her inventions, nothing is
lacking and nothing is superfluous
Leonardo da Vinci
MODELS FROM NATURE OF
INTEGRATED SYSTEMS DESIGN
Nature has been extremely successful in design at
a vast range of scales.
The elegance of the simplicity of a virus, and the
complexity of a blue whale or a giant redwood tree,
testify to the efficiency and effectiveness of natural
systems.
So, then, what can we learn from a tree as a system
that can be emulated in good design?
Tree as a design entity
It is a very efficient and effective “factory” that
makes oxygen, sequesters carbon, fixes nitrogen,
accrues solar energy, makes complex sugars and
food, creates microclimates, and self-replicates
Beyond a single tree, the ecological association and
community of trees makes use of what nature has
to offer.
Tree as a design entity
A collective of trees is more than just a group.
A stand of 100 trees is not the same as the product
of 100 times a single tree.
The collective system differs from the individual
tree’s system.
Tree as a design entity
Engineers and architects can learn much from
biologists, especially the concept of symbiosis.
There are synergies, tree-to-tree relationships, as
well as relationships between the trees and the
abiotic components
Principles of Biomimicry
The biomimicry model looks to nature as a learning
resource rather than merely as a natural resource
commodity to be extracted from the Earth.
nature would provide the models: solar cells copied
from leaves, steely fibers woven spider-style,
shatter proof ceramics drawn from mother of-
pearl, etc
Nature – scientific principles
Nature demonstrates beautifully how scientific
principles such as optimization and the
thermodynamic laws are evident and interwoven in
nature’s community of diverse and cooperative
systems.
Benyus’s principles of biomimicry
Nature runs on sunlight
Nature uses only the energy it needs
Nature fits form to function
Nature recycles everything
Nature rewards cooperation
Nature banks on diversity
Nature demands local expertise
Nature curbs excesses from within
Nature taps the power of limits
many innovations in material science
draw inspiration from nature
the study of lotus petals’ ability to repel rainwater
is now finding applications in “biometic paint” and
in surface treatment for concrete that absorbs
pollution from the air
EMERGING TOOLS FOR COLLABORATION,
SYNTHESIS, AND INNOVATION IN DESIGN

Open source software
Think Cycle
BIM Tools
Open source software
Open source software is counter to the traditional
approach of source codes, which both technically
and legally, protect the fundamental working
structure of the software from the general public.
Open-source software opens the operating system
to anyone with the interest and technical ability to
propose improvements or extend the capabilities of
the software tool
The emergence of open-source software has led to
the collaboration of a diverse collection of people
bringing varied experiences and creativity to the
development of these tools.
Think Cycle
At the Massachusetts Institute of Technology, a
group of graduate students in the Media Lab set up
an open, online structure to allow them to
collaborate on design and engineering projects.
BIM tools
Building information modeling (BIM) uses
computer technology to create a virtual
multidimensional models of a building as an
integrated part of the design process, not as an
afterthought for use in marketing the design as a
finished product
Building information modeling
(BIM)
This approach is revolutionary in the design
professions.
Most design software used in
architectural/engineering offices since the
introduction of computer aided design systems has
represented productivity gains through increased
efficiency but really has not represented major
advances beyond digitally representing primitive
lines, arcs, and circles to define buildings.
Building information modeling
(BIM)
Designers using BIM software can apply digitally bundled
information called objects to represent building
components such as windows and doors.
These models are enriched by their ability to represent a
much wider range of information on the physical
characteristics of the building.
The potential for these models to behave in an “intelligent”
manner provides the opportunity for exploration and
collaboration among design disciplines as well as with the
construction community.
The term integrated practice has been coined to describe
this approach, which represents both an opportunity and a
challenge for the architecture and engineering professions.
BIM approach
Better quality, greater speed, and lower cost by way
of improved efficiency
From a sustainable design perspective, the greatest
potential is for increased collaboration and
integration across design disciplines supporting the
promise of a trend toward systems solutions similar
to those found in nature
a more robust database and an adaptive expert
system are available to the design team to explore
and conduct more comprehensive life-cycle cost
models.
Integration and collaboration
To be an architect, engineer, or designer is to be an
agent of change, and by working collaboratively, we
have the potential to become the alchemists of the
future, transforming a collection of data and myriad
inputs to derive designs that protect and shape our
environment in a manner that benefits all.
The amount of “lead” is increasing exponentially, but
the opportunities for “gold” (innovation) are also
rapidly growing.
We may be tempted to take short cuts, but we must
remain steadfast in search of sound designs.
The common thread is adherence to nature’s rules as
codified in scientific principles. There is no substitute
for sound science in green design