'Cleaner' design and technology - a products life cycle

The following page of notes will cover:

Material selection
Manufacture
Distribution
Use
Repair and maintenance
End of life

Material selection

Source:

Their extraction and processing is costly both financially and environmentally

This is due to the vast amounts of energy required to convert ore into the finished product

Polymers are derived from crude oil, which is a finite resource, for this reasons designers must consider recycled materials to reduce consumption

The UK relies heavily upon imported raw materials, resulting in high transport costs and carbon dioxide emissions

Quantity:

Reduce the amount of materials used in order to conserve resources, which will in turn reduce energy consumption and pollution

Minimise material usage by redesigning products

Quality:

Consider using recycled materials to reduce consumption

Use materials that are recyclable

Depends on what the product is intended for

Range:

Use materials that don't need to be transferred from large distances away

Keep manufacturing sites close to the area of material extraction

Recyclability:

Use materials that can be recycled at the end of the products lifespan to reduce waste

Design products so that they can easily be recycled at the end of the products lifespan

Biodegradability:

Many polymers don't biodegrade very well over time and so waste often ends up in landfill

Many woods can be repurposed for other things, eventually the wood will biodegrade

Manufacture

Minimising energy use:

Use materials that use less energy during manufacture and produce less waste

Use more effcient manufacturing techniques/machines to reduce energy cost

Simplification of processes:

A simple design with fewer components to reduce materials use and assembly line

Use simpler manufacturing techniques

Achieving optimum use of materials and components:

Simpler components that are easier to machine or mould and produce less waste

Giving consideration to material form:

Different materials to reduce their weight or the quantity used

Using less materials

Giving consideration to material form:

A simplified or different work flow with improved quality control to reduce waste

Distribution

Efficient use of packaging:

Reducing/lightening the amount of packaging used in products

Optimise packaging use

Use bulk delivery of materials/JIT to reduce packaging

Reduction of transport:

Driving smoothly/efficiently

Use local resources to reduce transport

Geographical locations of distribution centres close to consumers

Alternative to fossil fuels:

Using trains for transport to reduce emissions (electric trains)

Using waterways for transportation where appropriate

Using electric vehicles

Use

Repair vs replacement:
Advantages of repair:

Cost effective

Less material waste

Extends the products lifespan

Advantages of replacement:

Latest technology

Relatively new products that are replaced can be used in the second-hand market

Energy efficiency:
Goal to reduce the amount of energy required to provide products and services

Insulating homes to reduce heat loss

Use more energy efficient machinery

Use less energy intensive

Efficiency ratings:
The energy efficiency of appliances is rated in terms of energy efficiency classes from A - G on the label, A being the most energy efficient, G the least efficient

Repair and maintenance

Standardisation:

Standardisation means all parts are of a fixed size

Makes it easier to find replacements and repair products

Parts can be quickly ordered

Modular construction:

Use of factory produced pre-engineered building units that are delivered to site and assembled as large volumetric components or as substantial elements of a building

Allows easy and quick replacement of broken modules

Already prefabricated to reduce repair times

Bought in parts:

Can be found easily to replace the broken ones

Standardised size so will be correct part

Can be quickly ordered

End of life

Design for disassembly:

Easy to dismantle for repair or resuse and so extending product life

Easy to seperate different materials for recycling

Easy to remove components that must be treated seperately for repair

Use as few different materials as possible

Mark the materials/polymers in order to sort them correctly

Avoid surface treatments in order to keep the materials 'clean'

Recovered material collection:

Materials are collected and then seperated so that they can be recycled and reused for other products

It stops materials ending up in landfil sites

Sorting and re-processing methods:

Material recovery facilityls (MRFs) sort out material and seperate them

They are then re-processed into new materials

Paper is a good example, it can be recycled/reprocessed many times

Energy recovery:

Recycling and reusing energy intensive metals that use a lot of energy from extraction

Steel/copper/aluminium can be recycled and repurposed without the need for lots of energy

Environmental implications of disposal to landfill:

MRFs struggle with unwanted items such as plastic bags so these often end up in land fill

Air pollution

Groundwater pollution

Biodiversity impacts

Soil fertility effects

Topic test:

Product Life Cycle Questions

'Cleaner' design and technology - a products life cycle

The following page of notes will cover:

Material selection

Quantity: Reduce the amount of materials used in order to conserve resources, which will in turn reduce energy consumption and pollution Minimise material usage by redesigning products

Quality: Consider using recycled materials to reduce consumption Use materials that are recyclable Depends on what the product is intended for

Range: Use materials that don't need to be transferred from large distances away Keep manufacturing sites close to the area of material extraction

Recyclability: Use materials that can be recycled at the end of the products lifespan to reduce waste Design products so that they can easily be recycled at the end of the products lifespan

Biodegradability: Many polymers don't biodegrade very well over time and so waste often ends up in landfill Many woods can be repurposed for other things, eventually the wood will biodegrade

Manufacture

Minimising energy use: Use materials that use less energy during manufacture and produce less waste Use more effcient manufacturing techniques/machines to reduce energy cost

Simplification of processes: A simple design with fewer components to reduce materials use and assembly line Use simpler manufacturing techniques

Achieving optimum use of materials and components: Simpler components that are easier to machine or mould and produce less waste

Giving consideration to material form: Different materials to reduce their weight or the quantity used Using less materials

Giving consideration to material form: A simplified or different work flow with improved quality control to reduce waste

Distribution

Efficient use of packaging: Reducing/lightening the amount of packaging used in products Optimise packaging use Use bulk delivery of materials/JIT to reduce packaging

Reduction of transport: Driving smoothly/efficiently Use local resources to reduce transport Geographical locations of distribution centres close to consumers

Alternative to fossil fuels: Using trains for transport to reduce emissions (electric trains) Using waterways for transportation where appropriate Using electric vehicles

Use

Repair vs replacement: Advantages of repair: Cost effective Less material waste Extends the products lifespan Advantages of replacement: Latest technology Relatively new products that are replaced can be used in the second-hand market

Energy efficiency: Goal to reduce the amount of energy required to provide products and services Insulating homes to reduce heat loss Use more energy efficient machinery Use less energy intensive

Efficiency ratings: The energy efficiency of appliances is rated in terms of energy efficiency classes from A - G on the label, A being the most energy efficient, G the least efficient

Repair and maintenance

Standardisation: Standardisation means all parts are of a fixed size Makes it easier to find replacements and repair products Parts can be quickly ordered

Modular construction: Use of factory produced pre-engineered building units that are delivered to site and assembled as large volumetric components or as substantial elements of a building Allows easy and quick replacement of broken modules Already prefabricated to reduce repair times

Bought in parts: Can be found easily to replace the broken ones Standardised size so will be correct part Can be quickly ordered End of life

End of life

Recovered material collection: Materials are collected and then seperated so that they can be recycled and reused for other products It stops materials ending up in landfil sites

Sorting and re-processing methods: Material recovery facilityls (MRFs) sort out material and seperate them They are then re-processed into new materials Paper is a good example, it can be recycled/reprocessed many times

Energy recovery: Recycling and reusing energy intensive metals that use a lot of energy from extraction Steel/copper/aluminium can be recycled and repurposed without the need for lots of energy

Environmental implications of disposal to landfill: MRFs struggle with unwanted items such as plastic bags so these often end up in land fill Air pollution Groundwater pollution Biodiversity impacts Soil fertility effects

Topic test:

Quantity:

Reduce the amount of materials used in order to conserve resources, which will in turn reduce energy consumption and pollution

Minimise material usage by redesigning products

Quality:

Consider using recycled materials to reduce consumption

Use materials that are recyclable

Depends on what the product is intended for

Range:

Use materials that don't need to be transferred from large distances away

Keep manufacturing sites close to the area of material extraction

Recyclability:

Use materials that can be recycled at the end of the products lifespan to reduce waste

Design products so that they can easily be recycled at the end of the products lifespan

Biodegradability:

Many polymers don't biodegrade very well over time and so waste often ends up in landfill

Many woods can be repurposed for other things, eventually the wood will biodegrade

Minimising energy use:

Use materials that use less energy during manufacture and produce less waste

Use more effcient manufacturing techniques/machines to reduce energy cost

Simplification of processes:

A simple design with fewer components to reduce materials use and assembly line

Use simpler manufacturing techniques

Achieving optimum use of materials and components:

Simpler components that are easier to machine or mould and produce less waste

Giving consideration to material form:

Different materials to reduce their weight or the quantity used

Using less materials

Giving consideration to material form:

A simplified or different work flow with improved quality control to reduce waste

Efficient use of packaging:

Reducing/lightening the amount of packaging used in products

Optimise packaging use

Use bulk delivery of materials/JIT to reduce packaging

Reduction of transport:

Driving smoothly/efficiently

Use local resources to reduce transport

Geographical locations of distribution centres close to consumers

Alternative to fossil fuels:

Using trains for transport to reduce emissions (electric trains)

Using waterways for transportation where appropriate

Using electric vehicles

Repair vs replacement:
Advantages of repair:

Cost effective

Less material waste

Extends the products lifespan

Advantages of replacement:

Latest technology

Relatively new products that are replaced can be used in the second-hand market

Energy efficiency:
Goal to reduce the amount of energy required to provide products and services

Insulating homes to reduce heat loss

Use more energy efficient machinery

Use less energy intensive

Efficiency ratings:
The energy efficiency of appliances is rated in terms of energy efficiency classes from A - G on the label, A being the most energy efficient, G the least efficient

Standardisation:

Standardisation means all parts are of a fixed size

Makes it easier to find replacements and repair products

Parts can be quickly ordered

Modular construction:

Use of factory produced pre-engineered building units that are delivered to site and assembled as large volumetric components or as substantial elements of a building

Allows easy and quick replacement of broken modules

Already prefabricated to reduce repair times

Bought in parts:

Can be found easily to replace the broken ones

Standardised size so will be correct part

Can be quickly ordered

End of life

Recovered material collection:

Materials are collected and then seperated so that they can be recycled and reused for other products

It stops materials ending up in landfil sites

Sorting and re-processing methods:

Material recovery facilityls (MRFs) sort out material and seperate them

They are then re-processed into new materials

Paper is a good example, it can be recycled/reprocessed many times

Energy recovery:

Recycling and reusing energy intensive metals that use a lot of energy from extraction

Steel/copper/aluminium can be recycled and repurposed without the need for lots of energy

Environmental implications of disposal to landfill:

MRFs struggle with unwanted items such as plastic bags so these often end up in land fill

Air pollution

Groundwater pollution

Biodiversity impacts

Soil fertility effects