CASE STUDY - BuroHappold Engineering · Design for accessibility W 2 C A 1 2 3 B Commissioning and...
Transcript of CASE STUDY - BuroHappold Engineering · Design for accessibility W 2 C A 1 2 3 B Commissioning and...
2 Sector Portfolio2 Sector Portfolio B U R O H A P P O L D E N G I N E E R I N G E D U C A T I O N
D AV I D A T T E N B O R O U G H B U I L D I N G | U N I V E R S I T Y O F C A M B R I D G E , U K
MA
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Nic
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3 Sector Portfolio B U R O H A P P O L D E N G I N E E R I N G E D U C A T I O N
D AV I D A T T E N B O R O U G H B U I L D I N G | U N I V E R S I T Y O F C A M B R I D G E , U K
IMA
GE
: ©
Nic
hola
s H
are
Arc
hite
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4 Sector Portfolio
D AV I D A T T E N B O R O U G H B U I L D I N G | U N I V E R S I T Y O F C A M B R I D G E , U K
BuroHappold pioneered a bespoke Sustainability Framework which aimed to reach beyond BREEAM by setting ambitious project specific targets across 10 headline themes and 50 sub-themes. Headline targets included a 40% reduction in operational carbon emissions, 30% reduction in water use per person and 60% total roof coverage for biodiverse green roofs.
A comprehensive evidence handbook was produced setting design, construction and post occupancy targets, developed through fully facilitated stakeholder engagement workshops with all building users, the University Estates Energy, Environment and Facilities Management teams. The framework was presented to the Cambridge City Council Planning Authority who fully supported its unique and robust approach to sustainability.
B E S P O K E S U S T A I N A B I L I T Y F R A M E W O R K
WAT
ER
E
DUCATION A
ND OUTREACH
BIODIVERSITY AND ECOLOGY ENERGY AND CARBON
B1 B2 B3 B4 E1 E2 E3 E4 E5 E6 E7 E8 E
9
Wa1
W
a2
Wa3
W
a4
EO
1
EO2
EO3
E
O4
EO5 E
O6
Local b
iod
iversity
Zo
olo
gy co
llection
Pro
cure
men
t in
op
erat
ion
Mo
nito
ring
of
bio
div
ersi
ty
Fabr
ic p
erfo
rman
ce
Vent
ilatio
nN
ew s
yste
m e
ffici
ency
Smal
l pow
er a
nd li
ghtin
g
Low carbon te
chnologies
Energy use in constru
ction
Total carbon savings
Energy use in operation
Commissioning and optimisation
Design of collaborative spaces
Design for accessibility
Publicising sustainable site operationsCollaboration across user groupsNOx emissions and refrigerantsExternal light pollution
Construction pollution
Embodied carbon
Environmental im
pact of new m
aterials
Responsible sourcing
Re-use of m
aterials
Designing for robustness
Desig
n out w
aste
Pro
vision o
f waste facilitiesC
ons
truc
tio
n w
aste
Op
erat
iona
l was
te
Cyc
le fa
cilit
ies
Acc
ess
and
way
findi
ng
Park
ingCon
stru
ctio
n tra
nspo
rt
Monito
ring tr
avel c
hoices
Reducing deliverie
s in operatio
n
User control
Day-lighting
Acoustic performance
Considerate construction
Improved food choices
Reduce water demand
Rainwater harvesting potential
Water use in construction
Water use in operation
Facilities for school groups
Visitor education
Museum
visitor numbers
Dem
onstrating project value to industry
Academ
ic case studiesB
uilding performance evaluation
HE
ALT
H A
ND
WE
LLBE
ING
TRANSPORT AND MOBILITY
WASTE
MATERIALS
POLL
UTI
ON
CO
LLA
BO
RA
TIO
N A
ND
INC
LUS
ION
W4
T1
T2
T3
T4
T5
T6
HW
1
HW
2
HW
3H
W4
HW
5
W3 W2 W1M5
M4
M3
M2
M
1
P3
P2
P1
CI4
CI3
CI2
CI1
Bespoke Sustainability Framework
WAT
ER
E
DUCATION A
ND OUTREACH
BIODIVERSITY AND ECOLOGY ENERGY AND CARBON
B1 B2 B3 B4 E1 E2 E3 E4 E5 E6 E7 E8 E
9
Wa1
W
a2
Wa3
W
a4
EO
1
EO2
EO3
E
O4
EO5 E
O6
Local b
iod
iversity
Zo
olo
gy co
llection
Pro
cure
men
t in
op
erat
ion
Mo
nito
ring
of
bio
div
ersi
ty
Fabr
ic p
erfo
rman
ce
Vent
ilatio
nN
ew s
yste
m e
ffici
ency
Smal
l pow
er a
nd li
ghtin
g
Low carbon te
chnologies
Energy use in constru
ction
Total carbon savings
Energy use in operation
Commissioning and optimisation
Design of collaborative spaces
Design for accessibility
Publicising sustainable site operationsCollaboration across user groupsNOx emissions and refrigerantsExternal light pollution
Construction pollution
Embodied carbon
Environmental im
pact of new m
aterials
Responsible sourcing
Re-use of m
aterials
Designing for robustness
Desig
n out w
aste
Pro
vision o
f waste facilitiesC
ons
truc
tio
n w
aste
Op
erat
iona
l was
te
Cyc
le fa
cilit
ies
Acc
ess
and
way
findi
ng
Park
ingCon
stru
ctio
n tra
nspo
rt
Monito
ring tr
avel c
hoices
Reducing deliverie
s in operatio
n
User control
Day-lighting
Acoustic performance
Considerate construction
Improved food choices
Reduce water demand
Rainwater harvesting potential
Water use in construction
Water use in operation
Facilities for school groups
Visitor education
Museum
visitor numbers
Dem
onstrating project value to industry
Academ
ic case studiesB
uilding performance evaluation
HE
ALT
H A
ND
WE
LLBE
ING
TRANSPORT AND MOBILITY
WASTE
MATERIALS
POLL
UTI
ON
CO
LLA
BO
RA
TIO
N A
ND
INC
LUS
ION
W4
T1
T2
T3
T4
T5
T6
HW
1
HW
2
HW
3H
W4
HW
5
W3 W2 W1M5
M4
M3
M2
M
1
P3
P2
P1
CI4
CI3
CI2
CI1
Bespoke Sustainability Framework
5 Sector Portfolio
D AV I D A T T E N B O R O U G H B U I L D I N G | U N I V E R S I T Y O F C A M B R I D G E , U K
IMA
GE
: N
icho
las
Har
e A
rchi
tect
s ©
Ala
n W
illia
ms
Phot
ogra
phy
E N G I N U I T Y T M P R O C E S SFor this project we used our Enginuity Process to create a collaborative team that focussed on delivering Efficient and Green Design.
Click to see the team of BuroHappold specialists that worked together.
6 Sector Portfolio B U R O H A P P O L D E N G I N E E R I N G E D U C A T I O N
D AV I D A T T E N B O R O U G H B U I L D I N G | U N I V E R S I T Y O F C A M B R I D G E , U K
E N G I N U I T Y T M P R O C E S S
E F F I C I E N T A N D G R E E N D E S I G N
Building services engineering (MEP)
Sustainability
Computational analysis
Fireengineering
Acoustic design
Lighting design
7 Sector Portfolio B U R O H A P P O L D E N G I N E E R I N G E D U C A T I O N
D AV I D A T T E N B O R O U G H B U I L D I N G | U N I V E R S I T Y O F C A M B R I D G E , U K
CONTAC T USMike Entwisle, Partner | Email: [email protected]
www.burohappold.com
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