Transcript
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DESIGN FOR BUILDABILITY

& DECONSTRUCTION CONSEQUENCES

Dr f Dejahang (BSc CEng, BSc (Hons) Construction Mgmt, MSc, MCIOB, PhD) http://www.cpi-team.com

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Science Art Religion Politics Scholarly Articles For Mathematics and Productivity

http://www.twitlonger.com/show/n_1sp9pjo?new_post=true

MICROSOFT OneDrive PPT’s PDF’s BOOK LESSONS Dr f Dejahang BSc CEng, BSc (Hons) Construction Mgmt, MSc, PhD

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BUILDABILITY AND THEDECONSTRUCTION CONSEQUENCES

1•Most buildings are designed with a life expectancy of just a few decades with no consideration of what will happen after their service life.

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BUILDABILITY AND THEDECONSTRUCTION CONSEQUENCES

2•One third of all solid waste going to landfill comes from building construction and demolition.

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BUILDABILITY AND THEDECONSTRUCTION CONSEQUENCES

3-The negative environmental impacts of this

waste are substantial.

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BUILDABILITY/DECONSTRUCTION

4•Such waste can be avoided or reduced by increasing the current rates of reuse and recycling of building materials and components.

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BUILDABILITY/DECONSTRUCTION

5

•One of the main obstacles to such reuse is that buildings are not designed for such ease of disassembly

•A developed knowledge base for design for disassembly does not yet exist.

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BUILDABILITY/DECONSTRUCTION

6•There are a number of related fields of knowledge that might offer information that will be of use in designing for disassembly.

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These areas include:-industrial design

-architectural technology-structural

engineering-building

maintenance-and buildability

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BUILDABILITY/DECONSTRUCTION

Research into this last area of buildability has already established some broad concepts and philosophies of how to achieve this goal by considering steps such as:

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BUILDABILITY/DECONSTRUCTION

ease of assemblyInformation on how to design for ease of assembly

This should be transferable to create knowledge of how to design for disassembly.

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DEFINING BUILDABILITY

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DEFINING BUILDABILITY

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RESEARCH INTO BUILDABILITY

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Buildability Systems

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BUILDABILITY/DECONSTRUCTIONDevelopment of the model relies

on a systems view of the design-construction process

This model seeks to understand the entire construction process as a system of interrelated activities and people

Each of which may have an impact on the construction process (refer to Figure below)

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Philip Crowther(Queensland University of Technology, Brisbane, Australia)

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BUILDABILITY/DECONSTRUCTION

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BUILDABILITY/DECONSTRUCTION

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BUILDABILITY/DECONSTRUCTION

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BUILDABILITY/DECONSTRUCTION

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BUILDABILITY/DECONSTRUCTION

SocialFactors

Technological

Factors

Managerial

Factors

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The stages of the building life cycle will include:

BUILDABILITY/DECONSTRUC

TION

•feasibility study•design•documentation•construction•commissioning• demolition or deconstruction.

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Buildability Principles

Different researchers have developed their principles in different ways but there is much common ground in these proposed strategies.

These strategies cover issues such as: access Timing skill levels Repetition tolerances and sequences.

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Construction Industry Research and Information Association (CIRIA)

BUILDABILITY/DECONSTRUCTION

• Carry out thorough investigation and design

• Plan for essential site production requirements

• Plan for a practical sequence of building operations and early enclosure

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Construction Industry Research and Information Association (CIRIA)

BUILDABILITY/DECONSTRUCTION

• Plan for simplicity of assembly and logical trade sequences

• Detail for maximum repetition and standardisation

• Detail for achievable tolerances

• Specify robust and suitable materials

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BUILDABILITY/DECONSTRUCTION

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BUILDABILITY/DECONSTRUCTION

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The Construction Industry Institute (CII) Constructability Task Force, by O’Connor, Rusch and Schultz

Buildability

•Construction-driven planning and programming

Buildability

•Design simplification

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Buildability

Buildability•Standardisation and repetition of design elements

Buildability•Specification development for construction efficiency

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BUILDABILITY/DECONSTRUCTION

Buildability•Modular and pre-assembly designs should be developed to facilitate prefabrication and installation

Buildability•Designs should allow for accessibility of labour, materials and plant

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Buildability

Buildability

•Designs should facilitate construction under adverse weather conditions

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Buildability issues1. Integration2. Construction knowledge3. Team skills4. Corporate objectives5. Available resources6. External factors7. Program8. Construction methodology9. Accessibility10. Specifications11. Construction innovation12. Feedback

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DESIGN FOR DISASSEMBLY PRINCIPLESWhile not all principles of buildability

will be relevant to design for disassembly

it is also true that not all principles of design for disassembly will come from buildability.

This table shows only those principles that have been informed by buildability sources.

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BUILDABILITY/DECONSTRUCTION

Minimise the number of different types of components

This will simplify the process of sorting on site and make the potential for reprocess more attractive due to the larger

quantities of same or similar items.

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BUILDABILITY/DECONSTRUCTION

Use an open building system where parts of the building are more freely interchangeable and less unique to one

application

This will allow

alterations in the building

layout through

relocation of component

without significant

modification

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BUILDABILITY/DECONSTRUCTION

Use modular design use components and pre-

assembledsubassemblies that are

compatible with other systems both dimensionally and

functionally Use assembly technologies

that are compatible

with standardbuilding practice

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BUILDABILITY/DECONSTRUCTION

Try to avoid specialist

technologies

It will make disassemblydifficult to perform and may require specialist labour andequipment that makes the

option of reuse more difficult

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Provide access to all parts of the building and all

components

Ease of access will allow ease of disassembly

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If possible allow for components to be recovered from within the

building TRY TO AVOID

use of specialist plant equipment

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BUILDABILITY/DECONSTRUCTIONUse components

that are sized to suit the intended means of handling

Allow for various possible handling

options at all stages of :assembly,

disassembly, transport,

reprocessing, and re-

assembly

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BUILDABILITY/DECONSTRUCTION

Provide realistic tolerances to allow

for movement during

disassembly

The disassembly process may

require greater

tolerances than the

manufacture process or the initial assembly process

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BUILDABILITY/DECONSTRUCTIONDesign

joints and connectors

to withstand repeated

useAllow for parallel

disassembly rather than sequential

disassembly

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This will allow

components or materials

be removed without

disrupting other

components or material

Use prefabricated subassemblies and a system

of mass production - to

reduce site work and allow greater control

over component quality and conformity

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BUILDABILITY/DECONSTRUCTION

Sustain all information on the building

manufacture and assembly process


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