Sustainability for designers - continue to develop products that meet current needs, while conserving the environment for future generations.
Key terms
Term
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Definition
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Example
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Renewability
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The ability to replenish itself and therefore can last indefinitely.
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Solar will virtually never run out of energy.
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Renewable sources
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Natural source that replenishes itself or is inexhaustible (never runs out).
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Non-renewable sources
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The natural source that does not replenish itself at a sustainable rate (equal to or lower than its extraction).
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Fossil fuels like the name suggests are fossils and take millions of years to form, and at the rate that we use them, we’ll run out in less than 100 years.
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Resource
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Raw material (in natural form)
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Oil in the ground; Wind
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(Resource) Reserve
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The storage of a natural source that can be identified, quantified, and qualified.
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Reservoir, battery
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Proven - accessible, readily available
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Fossil Fuels
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Probable - in an experimental state
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Solar power, Tidal energies
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Design for Manufacturing (DfM)
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Designing taking account for assembly. Easing the process of manufacturing to ensure product quality and...
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Design for Disassembly (DfD)
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Designing for maintenance and disposal. Easing the process of repair and sorting for recycling. Standardization of parts
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Process Streamlining
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The reduction of manufacturing
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Renewable energy sources
The general advantage of renewables is that they do not emit any CO₂, require little maintenance, thus saving money over an extended period.
Source
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Method
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Advantages
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Disadvantages
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Latest Developments
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Wind
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Through the circular motion created by wind, turbines generate energy
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New technologies are currently being developed, increasing the efficiency and lowering the cost of wind energy.
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Solar
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Through photovoltaic cells, the panels capture the energy from solar radiation
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In recent years installing shingles (solar roof tiles) has become more accessible and is helping to avoid visual pollution.
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Hydro
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Through the circular motion created by the flow of water, turbines generate energy.
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Private companies supported by crowdfunding are developing ‘micro’ hydroelectric plants for low-income areas.
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Biomass:
Biofuel
Biogas
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Through the digestion/ combustion of biowaste, energy is released and captured.
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In developing, areas in India businesses such as Husk Power Systems provide farmers with cheap renewable electricity from their rice waste.
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Waste mitigation strategies
The reduction of waste material. The general advantage is that it is often cheaper than buying a new product.
Term
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Definition
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Disadvantages
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Example
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Dematerialization
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The reduction of raw materials and energy used during manufacturing, usage, and waste at disposal.
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Re-Use
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Prolonging a product/component’s lifespan by using it for a different or same purpose.
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Glass jars, plastic water bottles
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Repair
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Prolonging a product's lifespan by restoring a product back into working condition
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Car maintenance,
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Recondition
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Old parts, old product - by cleaning up the product to the original state
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Refurbish
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New parts, old product - by repairing and upgrading
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Recycling
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The process of recovering waste for manufacturing material or energy production.
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Re-engineer
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The revision of a traditional design to reduce cost, waste, and improve/increase ease of use, performance, and quality.
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Legislation
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An incentive to make manufacturers use recycled materials, which prompts the public to recycle.
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Temporary
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External motivation
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Installation of wind power in The Netherlands
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Take back: Manufacturers are responsible to take back outdated/obsolete products and recycle them. |
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Technological convergence
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The combination of multiple types of technologies into one product to reduce space and resources.
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Smartphone - phone, camera, microphone, gaming device, computer...
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Eco-labeling
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A label that gives information to the consumers about the environmental impacts of the product
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Mitigation of environmental impacts
In general, the drivers to these methods are consumer pressure and legislation.
Eco Design
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Green Design
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Clean Technology
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Sustainable Design
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Designing for the environment, based on materials, energy, and pollutants/waste.
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The reduction of impact on nature while in use (incremental).
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The reduction of impact during the manufacturing processes.
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Total embodied energy, from conceptualization to disposal/regeneration
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Uses concepts such as Cradle to Cradle instead of Cradle to Grave. |
The focus of environmental issues through:
- Use of recyclable, nonpoluting and nontoxic materials
- Efficiency of product
- Disposal instructions
- Labeling
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Ensuring a neutral impact or minimizing negative impacts through:
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Promoting positive impacts
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Conserving natural resources
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Reduction of pollution/waste
- Reducing energy during manufacturing
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Green Products
Design objectives of green products:
Increasing
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Reducing
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Efficiency of materials and products
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Planned obsolescence
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Display of correct package disposal methods
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Ease of recycling process, through dematerialization
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Life Cycle Analysis - taking account the impacts that a product throughout its life. Through planned obsolescence designers attempt to increase longevity and reduce the impact at the disposal stage.
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Evaluation of sustainability:
Factor |
Question |
Raw materials used |
Are you using materials that can be recycled and are excavated? |
Toxicity |
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Energy during production |
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Production methods |
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Packaging |
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Atmospheric pollutants |
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Disposal issues |
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Drivers:
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Consumer awareness
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Visual pollution
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Carbon Gas emissions
Life cycle analysis
The Economy of Products / Loops
Types of Philosophies
Interpretation
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Cradle to Cradle
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Cradle to Grave
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Explanation
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Take -.
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Advantages
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Editors- admin_andrei - 976 words.
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