Difference between revisions of "project04:P4"

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'''Description'''
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Hyperbody has set an exercise for students who are graduation on the designstudio. For this exercise the student needs to develop a proposal for 6500-7000 sq. m. of student housing on the Green Village in Delft, which must comply on the following four demands. First, the building needs to be able to control its climate according to environmental conditions. Second, the CO2 of both the construction and the consumption of the building should be sufficiently reduced to its emissions. Third, generators of renewable energy should be integrated in the architecture to provide the building of power. And fourth, the integration of computational tools in both the design and fabrication of the building. <br>
  
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The site offers enough space for the building to use advantage of external weather condition like the wind and sun. These conditions could arrange a part of the climate within the building. This passive design strategy prevents additional energy consumption of an active system. Using computational tools I can optimise the shape of the building towards a desired passive climate solution. <br>
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To reduce further CO2 emission, the building needs to be efficient. Meaning two things. First, optimise the fabrication and assembly process to a minimum amount of energy. And second, extend the lifespan of the material by understanding the material properties and designing the product for possible future reuse. Within the studio of Hyperbody I choose the theme “Robotic Building” to develop the building components that fits the requirements of precision and mass customisation. CNC technology can offer the solution.  <br>
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Because I aim for a longterm preservation of the building, I have to take in account that the program of the building can change in the future from student housing to something else. To adopt to this possible change I need to design the spatial layout flexible. This will include the student housing itself but also the infrastructure of the facilities such as electricity, water and drain inside the building. This possible change, the maintenance of the building and possible obsolescences of building components will require a subtile distinction from the main structure of the building to preserve the building as long as possible. <br>
  
 
[[File:WOODSTOCK P2 herkansing.jpg | 850px]]
 
[[File:WOODSTOCK P2 herkansing.jpg | 850px]]

Revision as of 06:47, 31 January 2017

Presentation

Description


Hyperbody has set an exercise for students who are graduation on the designstudio. For this exercise the student needs to develop a proposal for 6500-7000 sq. m. of student housing on the Green Village in Delft, which must comply on the following four demands. First, the building needs to be able to control its climate according to environmental conditions. Second, the CO2 of both the construction and the consumption of the building should be sufficiently reduced to its emissions. Third, generators of renewable energy should be integrated in the architecture to provide the building of power. And fourth, the integration of computational tools in both the design and fabrication of the building.

The site offers enough space for the building to use advantage of external weather condition like the wind and sun. These conditions could arrange a part of the climate within the building. This passive design strategy prevents additional energy consumption of an active system. Using computational tools I can optimise the shape of the building towards a desired passive climate solution.

To reduce further CO2 emission, the building needs to be efficient. Meaning two things. First, optimise the fabrication and assembly process to a minimum amount of energy. And second, extend the lifespan of the material by understanding the material properties and designing the product for possible future reuse. Within the studio of Hyperbody I choose the theme “Robotic Building” to develop the building components that fits the requirements of precision and mass customisation. CNC technology can offer the solution.

Because I aim for a longterm preservation of the building, I have to take in account that the program of the building can change in the future from student housing to something else. To adopt to this possible change I need to design the spatial layout flexible. This will include the student housing itself but also the infrastructure of the facilities such as electricity, water and drain inside the building. This possible change, the maintenance of the building and possible obsolescences of building components will require a subtile distinction from the main structure of the building to preserve the building as long as possible.

WOODSTOCK P2 herkansing.jpg WOODSTOCK P2 herkansing2.jpg WOODSTOCK P2 herkansing3.jpg WOODSTOCK P2 herkansing4.jpg WOODSTOCK P2 herkansing5.jpg WOODSTOCK P2 herkansing6.jpg WOODSTOCK P2 herkansing7.jpg WOODSTOCK P2 herkansing8.jpg WOODSTOCK P2 herkansing9.jpg WOODSTOCK P2 herkansing10.jpg WOODSTOCK P2 herkansing11.jpg WOODSTOCK P2 herkansing12.jpg WOODSTOCK P2 herkansing13.jpg WOODSTOCK P2 herkansing14.jpg WOODSTOCK P2 herkansing15.jpg WOODSTOCK P2 herkansing16.jpg WOODSTOCK P2 herkansing17.jpg WOODSTOCK P2 herkansing18.jpg WOODSTOCK P2 herkansing19.jpg WOODSTOCK P2 herkansing20.jpg WOODSTOCK P2 herkansing21.jpg WOODSTOCK P2 herkansing22.jpg WOODSTOCK P2 herkansing23.jpg WOODSTOCK P2 herkansing24.jpg WOODSTOCK P2 herkansing25.jpg WOODSTOCK P2 herkansing26.jpg WOODSTOCK P2 herkansing27.jpg WOODSTOCK P2 herkansing28.jpg WOODSTOCK P2 herkansing29.jpg WOODSTOCK P2 herkansing30.jpg WOODSTOCK P2 herkansing31.jpg WOODSTOCK P2 herkansing32.jpg WOODSTOCK P2 herkansing33.jpg WOODSTOCK P2 herkansing34.jpg WOODSTOCK P2 herkansing35.jpg WOODSTOCK P2 herkansing36.jpg WOODSTOCK P2 herkansing37.jpg WOODSTOCK P2 herkansing38.jpg WOODSTOCK P2 herkansing39.jpg WOODSTOCK P2 herkansing40.jpg WOODSTOCK P2 herkansing41.jpg