1:50 ELEMENT EXPLODED AXONOMETRIC
A
B
C
D
A B C D
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EXISITING STRUCTRUE CORSICAN PINE CLAD STEEL PRIMARY FRAME ALUMINIUM SECONDARY SUPPORT FRAME 50MM STONE CLAD FACADE
D
1:10 ELEMENT CONSTRUCTION AXONOMETRIC C
A
A
B A
E B
B
A B C D E F
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20X20MM TIMBER BATONS CORSICAN PLYWOOD PANELS 300X100MM RHS STEEL BOLT STEEL FIXING PLATE CONCRETE PAD
C
D E F
1: 500S I TEPLAN
Ri v erS ev er n
Ri v erS ev er n
1: 200FI RS TFLOORPLAN
Obs er v at i on pl at f or m
1: 500NORTHEAS TELEV A TI ON
1: 100CROS SS ECTI ON A: A
A
A
1: 500LONGS ECTI ONB: B
0000mm
3800mm
A
A
1: 50BA YANDS ECTI ONELEV A TI ON
Ri v erS ev er n
C
D A
E GFH
B
c
J
S ec t i onalEnv i r onment alDi agr am C: C
c
P
O
M
Q
K NI L
The bunker is purposefully stark and cavernous. Although windows stretch the full span of the building they are only narrow at 600mm high, To light the interior I would use Kos Round 100 LED spotlights. These would be installed into the recesses of the ribbed ceiling to appear as a more seamless fixture.
The Bunker is both naturally and mechanically ventilated, this allows for user control as mechanical systems may not always offer the most comfortable environment
0000mm -230mm
-800mm
The Bunker is constructed out of thick concrete 800m walls including insulation, giving the building a high thermal mass, keeping it warm in winter, yet cooler in summer.
-3800mm
-3800mm
-4520mm
Heat Pump Plant Room (Inside Bunker)
The Bunker is roughly 800SQM, and would use up to 44,000KWH in a year. I want to employ an off grid strategy to the bunker so it can be cut off from the outside world and still survive. To generate some of this power, Hydroelectric turbines would be placed along the riverside to harvest energy
When additional heating it needed, The bunker employs the use of Geothermal system, plunging water 120-182m below ground level in a closed system, to heat it and then push it through the underfloor heating pipes.