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Joanna Himes Chris BrennyDavid JohanssonNiko KubotaKai Salmela
ARCH5516
Luminous and Thermal DesignEcological Design for the 21st CenturymnZED Lab Design: Phase 3
SITE ANALYSIS + CONCEPTS
SITE AND SEASONAL QUALITIES
ECOLOGICAL CONNECTIVITY ECOLOGICAL LANDSCAPE CONCEPT
ARCHITECTURAL CONCEPT
SUN PATHDEC. 21
PREDOMINANTWINTER WIND
PREDOMINANTSUMMER WINDPUBLIC
FRONT
HEAVILY SHADED
NORTHRUP
CH
UR
CH
ST.
AR
TE
RY
NORTHRUP MALL
BU
NG
E
PILLSBURY
SUN PATHJUN. 21
CORE: a new programmatic core is the counterpart of the piazza of the courtyard. It serves as a circulation backbone, connecting the formerly disparate departments of architecture, landscape architecture, and the CSBR, catalyzing interaction between these departments and integrating the CSBR into the university culture. The core also serves as a passive strategy; it pours diffuse north light into the new atrium and pulls stale air out of the building through stratification.
REACTION: the inner-facing and universal Cerny building is acknowledged and re-interpreted in the CSBR addition. The reclusive “O” is broken into a South-facing “C”, exposing the inner loop circulation to generous south light and opens the building to cool summer breezes.
LAYERS: the CSBR addition is conceptualized as a series of delaminated layers, gradually opening to the South of the building, forming a gradient of spaces from seasonally exposed outside courtyards to semi-enclosed meeting spaces to fully sheltered workspaces. Layers are exposed on the East and west facades, but continue through the building, defining separations in program.
LABSCSBRL.ARCH
ARCH
OUTSIDE VIEWS
SOUTHERN GAIN
CLOSED TONORTH WINDS
Campus ecological corridors, populated with native vegetation...
...and linear rain gardens running south toward the Mississippi River...
..transition with the dramatic topography of the river bank...
... terminating at the Mississippi river ecosystem
Intimate front porch off of conference room
Gathering space on public west front
Native seasonalshading device
Rain garden delineating southern boundary
Extensive sedum green roof above courtyard
Joanna Himes Chris BrennyDavid JohanssonNiko KubotaKai Salmela
ARCH5516
Luminous and Thermal DesignEcological Design for the 21st CenturymnZED Lab Design: Phase 3
DAYLIGHT AND THERMAL PROGRAM
DAYLIGHT PROGRAM
THERMAL PROGRAM
RESEARCHERS200-350 lux
OFFICES & RECEPTION200-750 lux
CLASSROOMS300-750 luxDAYLIGHTING LAB
150-300 lux
MATERIALS LAB150-300 lux
SITE & WATER LAB300-750 lux
DEMONSTRATION LAB300-750 lux
ENERGY & INDOORAIR QUALITY LAB
300-750 lux
CONFERENCE 300-750 lux
PORCH SUNSPACE1200+ lux
CIRCULATION 300-1500 lux
CIRCULATION 300-1500 lux
ATRIUM 750-1200 lux
RESEARCHERS65-78°
OFFICES & RECEPTION65-78°
CLASSROOMS65-78°DAYLIGHTING LAB
65-78°
MATERIALS LAB65-78°
SITE & WATER LAB65-78°
DEMONSTRATION LAB65-78°
ENERGY & INDOORAIR QUALITY LAB
65-78°
CONFERENCE 65-78°
PORCH SUNSPACE45-85°
OUTSIDE-50° - 110°
OUTSIDE-50° - 110°
OUTSIDE-50° - 110°
CIRCULATION 57-80°
CIRCULATION 57-80°
ATRIUM 60°-80°
NORTH ^
NORTH ^
4TH FLOOR
4TH FLOOR3RD FLOOR
3RD FLOOR
Pergolas create shaded outdoor spaces
Conference room with visual connection to atmospheric conditions
Ambient north lighting in researchers offices
South facing corridors feed light into adjacent rooms
Ample light through central core
Outdoor demonstration area with protection from wind andconnection to interior space
Lab spaces set back from glass to reduce allow only indirect daylight
Deep overhangs on 4th floor corridor allows direct sun in winter but shade in summer
ZONE 1: THERMAL FLUX57-80° F (conditioned range)
Most direct connection to exterior thermal conditions. Temperature shifts with season, sunlight intensity, and weather.
ZONE 2: SOUTH FACING65-78° F (conditioned range)
South facing areas that take full advantage of direct passive gains. Shading devices allows occupants to regulate temperature.
ZONE 3: NORTH FACING65-78° F (conditioned range)
Fewer windows and increased insulation for thermal stability. Limited passive gains from adjacent zones.
THERMAL PROGRAM ZONES
ZONE 1: SOLAR FLUX 500-1500 lux
Most direct connection to exterior atmospheric conditions. Shifting light conditions according to season, time, and weather.
ZONE 2: FULL DAYLIGHTING 300-750 lux
Direct sunlight controlled through louvers and light shelves to minimize need for electrical lighting during occupancy hours.
ZONE 3: AMBIENT DAYLIGHT 200-350 lux
Ambient north light provides lower but even light quality with points of task lighting as needed.
ZONE 4: MINIMAL DAYLIGHT0-300 lux
Low occupancy spaces with minimal daylighting required.
DAYLIGHT PROGRAM ZONES
Joanna Himes Chris BrennyDavid JohanssonNiko KubotaKai Salmela
ARCH5516
Luminous and Thermal DesignEcological Design for the 21st CenturymnZED Lab Design: Phase 3
ENVELOPE & SYSTEMS INTEGRATION
ENVELOP PRECEDENTS
LIGHTING AND HEATING STRATEGY (PASSIVE + ACTIVE)
WALL SECTION SYSTEMS INTEGRATION
Waldsee BioHaus, Bemidji, MN [Stephen Tanner of INTEP, Inc]Porextherm Vacupor® VIPs meet the requirements of the German energy conservation provision EnEV without dramatically increasing the insulation thickness. They allow a slimness, which offers more space for design and is ideal for inside and outside areas.
Waldsee BioHausMade of spruce/fir, cork, larch, and aluminum cladding, Optiwin’s 3 wood window is the “world’s finest window.” It achieves the German Passivhaus Certification with an over all R-value of 8.0.
Toronto City Hall, Toronto, Canada [PLANT Architect Inc. / Shore Tilbe Irwin & Partners]An extensive green roof offers a delightful outdoor space for work and demonstrations as well as thermal insulation in the winter and cooling in the summer. Local vegetation will connect with the surrounding environment, attract wildlife, and collect/filter rain.
School Complex, Pichling, Austria [Loudon + Habeler]In the winter, fresh air is pre-heated through geothermal heat exchange and pre-cooled in the summer. Exhaust air is collected for heat recovery through rotary heat exchanger. The core of the building will act as a thermal chimney.
Omega Center, Rhinebeck, New York (BNIM Architects)The Omega Center takes full advantage of photovoltaic roof panels, geothermal, thermal masses, natural ventila-tion, passive cooling, daylighting, passive heating, and shading.
Tall, native plants filter direct summer light
Overhang designed to maximize direct solar
gain in winter
Operable louvers block out high summer sun
Solar panels angled based on 44° north latitude
Radiant heat system integrated with thermal mass to supplement solar gain
COOLING AND VENTILATION STRATEGY (PASSIVE + ACTIVE)
Operable windows for passive ventilation
Existing forces air system Operable windows Air/Heat exchange unit
Radiant Heating System
Radiant Cooling System
Geothermal ground loop supports heating & cooling systems
Atrium facilitates passive ventilation
through stratification
Double-sealed window with cork separator
Triple-pane glass with argon fill
Concrete facing panels
Weatherproofing
Rigid insulation (protects VIP from puncture)
Porextherm vacuum insulated panel (primary
insulation)
OSM
Moisture barrier
Gypsum board
Airducts
Concrete floor slabVentilation duct
Lighting strip
Radiant cooling ceiling panel
VIP panel insulation
Radiant floor system
Louver system
Thermal/daylightcontrol shutters
Solar voltaic placement
Closed ground loop geothermal
Joanna Himes Chris BrennyDavid JohanssonNiko KubotaKai Salmela
ARCH5516
Luminous and Thermal DesignEcological Design for the 21st CenturymnZED Lab Design: Phase 3
BUILDING DESIGN
FLOOR PLANS
LAB
LAB
LAB
LAB
LABCLASSROOMS
OFFICESRESEARCHERS
CONFERENCE
LOBBY
MENS
WOM.
MENS
WOM.
MECH
MEC
H
MECH
PORCH/SUNSPACE
OUTDOOR LAB/DEMO
CLASSROOM GREEN SPACE
PUBLIC GREEN SPACE
OUTDOOR LAB/DEMO
WEST RAINGARDEN
LAB
LAB
LAB
LAB
LABCLASSROOMS
OFFICESRESEARCHERS
CONFERENCE
LOBBY
MENS
WOM.
MENS
WOM.
MECH
MEC
H
MECH
PORCH/SUNSPACE
OUTDOOR LAB/DEMO
CLASSROOM GREEN SPACE
PUBLIC GREEN SPACE
OUTDOOR LAB/DEMO
WEST RAINGARDEN
MATERIAL INVENTORYCERNY BUILDING MNZEDHOLL BUILDING
RELATIONSHIP TO CERNY: the CSBR offices acknowledges and reinterprets the aesthetic of the existing building. While the universal regularity of the existing windows of the first two floors are not directly continued upwards, the eight-foot spacing of the windows forms the basis of columnar structure and the expanding spacing of the layers. The black-painted steel of the floor bands are carried up into the vertical louvers of the addition, while the mass of the brick changes to board-formed concrete, drawing on existing materials.
NORTH FACE: The north and south faces of the addition, rather than expressing the cross-section of the concept, show the faces of these slices. The north face is made up of five compressed layers, the outermost of concrete, the inner layers are a soft underbelly of wood, barely visible in the window sections. The window placement articulates inner program needs; narrower windows reflect spaces adjacent to the light-filled core space, wider windows are adjacent to spaces higher daylighting needs. The form of the windows is a hybrid between the vertical slots present in the Cerny building and the punched squares in the Holl addition.
SOUTH ELEVATION
1/16” = 1’-0” N ^
4TH FLOOR
3RD FLOOR
1/16” = 1’-0”
1/16” = 1’-0”
1/16” = 1’-0”
WEST ELEVATION
NORTH ELEVATION
Joanna Himes Chris BrennyDavid JohanssonNiko KubotaKai Salmela
ARCH5516
Luminous and Thermal DesignEcological Design for the 21st CenturymnZED Lab Design: Phase 3
DAYLIGHT AND THERMAL STUDIES
ROOM ILLUMINANCE STUDYBASELINE: NO SHADING DEVICES FINAL DESIGN: OPERABLE SHUTTERS AND LIGHT SHELF
BASELINE DAYLIGHTINGFloor 3 Floor 4
SU
MM
ER
SO
LSTI
CE
, 12:
00E
QU
INO
X, 1
2:00
WIN
TER
SO
LSTI
CE
, 12:
00
Floor 3
Floor 3
Floor 4
Floor 4
PERSPECTIVE VIEWS
DAYLIGHT AUTONOMY UDI (USEFUL DAYLIGHT ILLUMINANCE)
FINAL DAYLIGHTINGFloor 3 Floor 4
SU
MM
ER
SO
LSTI
CE
, 12:
00E
QU
INO
X, 1
2:00
WIN
TER
SO
LSTI
CE
, 12:
00
Floor 3
Floor 3
Floor 4
Floor 4
BASELINE THERMAL
BUILDING LOADS
THERMAL COMFORT
GAINS BREAKDOWN
77 Kbtu PER SQ. FT.
FINAL THERMAL
BUILDING LOADS
THERMAL COMFORT
GAINS BREAKDOWN
36 Kbtu PER SQ. FT.
%
Lux
Lux
Lux
Lux
Lux
Lux
FINAL W/ RENEWABLE ENERGY
0 Kbtu PER SQ. FT.
Building Energy Use
(1,000,000)
(500,000)
-
500,000
1,000,000
1,500,000
2,000,000
KBtu
Total Solar Thermal Output (kBtu) 0 0 0 0
PV production (kWh) 0 0 0 -434,001
Total Ann. Equip. Load (kWh) 231,824 231,824 208,642 177,732
Total Ann. Lighting Load (kWh) 207,424 207,424 122,083 89,171
Total Ann. Cooling Load (kBtu) 262,864 221,763 196,429 63,891
Total Ann. Heating Load (kBtu) 1,101,406 1,201,934 411,158 103,312
Code Base Baseline Optimized Design Final Design
Project 2 Project 3Code Base Baseline Optimized Design Final Design
Load Type Case Case Case CaseTotal Ann. Heating Load (kBtu) 1,101,406 1,201,934 411,158 103,312Total Ann. Cooling Load (kBtu) 262,864 221,763 196,429 63,891Total Ann. Lighting Load (kWh) 60,828 60,828 35,801 26,150Total Ann. Equip. Load (kWh) 67,984 67,984 61,185 52,121
TOTAL ENERGY USE (kBtu) 1,803,788 1,863,215 938,514 434,270 TOTAL ENERGY USE INTENSITY (kBtu/SF) 107.0 110.5 55.7 25.8
PV production (kWh) - - - 127,273Total Solar Thermal Output (kBtu) - - - 0Total Renewable Energy Production - - - 434,269
Net Energy Use (production) 1,803,788 1,863,215 938,514 1 Net Energy Use Intensity 107 111 56 0
Joanna Himes Chris BrennyDavid JohanssonNiko KubotaKai Salmela
ARCH5516
Luminous and Thermal DesignEcological Design for the 21st CenturymnZED Lab Design: Phase 3
EXPERIENTIAL QUALITIES
LIGHT MODEL STUDY RENDERED VIEWS
Isometric view of west facade
Dec 21, 9:00 Dec 21, 12:00 Dec 21, 15:00
Jun 21, 9:00 Jun 21, 12:00 Jun 21, 15:00
Mar 21, 9:00 Mar 21, 12:00 Mar 21, 15:00
Jun 21, 15:00 Mar 21, 15:00
Operable shutters linked to thermal flux zone allow users inside of rooms to control the amount of heat and light entering the space.
View from flux space looking south
View from flux space looking east
Closed – Block heat/light from flux spaceAngled open – Allow some heat, block direct lightOpen – Take full advantage of passive solar heat and outside light levels