THE INHABITABLE VOID ANTONIA STANEV, 20509801
Beyond the forest in Noboribetsu, rests a spa dug into the mountain, undefined by time, it seems to have been standing there forever but one can’t be sure. Visitors bathe in the hot mountain water and breathe in the mountain air, immersed in a curated ritualistic sequence of bathing, dining and relaxing in the landscape. The monolith mass is carved on the inside, the voids becoming inhabitable spaces. As the spa progresses towards the river it becomes lighter, more is carved away from its heaviness, until the only indication of its presence is a column, a stair or remnants of a wall guiding one to the entrance. Space extends, contracts, expands, narrows, constricts, widens and straightens. To fully create the right atmosphere to emerse one into this experience, a large spectrum of climates occur within the long building, progressing from outdoor open spaces to fully enclosed conditioned spaces, to spaces that change in climate depending on the time of day. The natural environment is enhanced in certain spaces while comfort takes over in others. Openings and framed views to the landscape become important as one travels deeper into the building, and light becomes more and more scarce. The light is as important of an element as the wall, guiding one through the building, and instilling an otherwordly feeling to the spa. Chthonic.
PARTI DIAGRAMS //LOUIS KAHN AND THE SCOTTISH CASTLE
KAHN’S SKETCH PLAN STUDY TRIM CASTLE
KAHN’S SKETCH PLAN STUDY ORFORD CASTLE
KAHN’S SECTION STUDY
CONCEPT DIAGRAMS
FROM THE EARTH
MASSING
Inspired by the volcanic rocks and mountainous landscapes in Noboribetsu, the spa is born from large monolothic stones.
The spa takes a simple form, setting up an enfilade, a sequence of experiences towards the river.
CARVE THE EXPERIENCE
LAYERS OF DISINTEGRATION AND LIGHT
The mass is carved out to create inhabitable spaces within the stone, shaped for directional purposes, light penetration and use.
As the building becomes lighter, and extends towards the river, its components break apart becoming fragments interwoven in the landscape.
PROGRAM 1. OUTER VESTIBULE 2. RECEPTION 3. LOUNGE/GATHERING SPACE 4. INNER VESITBULE 5. CHANGING ROOMS 6. TEPIDARIUM 7. CALDARIUM 1 8. SUDATORIUM 9. FRIGIDARIUM 10. CALDARIUM 2 11. KITCHEN 12. STORAGE 13. OFFICE 14. GREENHOUSE 15. LODGE MANAGER 16.POTTERER STUDIO 17. ACCOMODATIONS 18. LAUNDRY ROOM 19. W/C AND SHOWERS 20. CISTERN 21. POTTERER’S GARDEN 22. ELECTRICAL ROOM 23. MAINTENANCE ROOM 24. WASTE MANAGEMENT ROOM 25. MECHANICAL ROOM
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FLOOR PLAN 1:100
SUSTAINABILITY STRATEGIES Winter Solstice 70 degrees
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WIND EXPOSURE
SUN ORIENTATION
RAIN HARVESTING
EARTH SHELTERING
The building is positioned to avoid high winds, minimizing the facades directly facing strong winds and burying them in the hill of the site. The buildings against the hill are protected by the main building. The minimal exposure to the cold winds of the region and the hill protection reduces air infiltration within the building, and the hill helps reduce the amount of warm air escaping from the inside spaces. The main building is long and narrow, encouraging cross ventilation and air flow from its east and west sides.
The east and the west facades of the building are maximized, as a passive solar heating strategy, since the site’s south side is blocked by the mountain hill. Direct sunlight is of low intensity due to the forest surrounding the building. The sunlight enters the building all year round, though wall openings and skylights. The baths are made of volcanic rock and concrete, materials chosen for their thermal mass, capturing solar heat during the day and releasing it at night to maintain a comfortable environment.
The building roofs slope in two directions (South East), one towards the hillside and the other towards the east, in order to collect rainwater into the cistern, and to be used as part of the building’s water supply. The natural slope inclination of the ground is used to direct water without much energy consumption used for pumping the rainwater through the site.
The building takes advantage of the hillside of the site in order to bury the south walls into it, anchoring the spa into the mountain. This is a passive technique known as earth sheltering, using the earth’s thermal mass for the retaining and transferring of heat and maintaining a stable comfortable indoor environment, with reduced heat loss and energy consumption for heating and cooling.
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AXONOMETRIC NTS
The baths are a story of light. The visitor is welcomed by the sacred light from the central space, a celebration of light, the soul of the project. The baths, open to the elements, are heavy in mass, primordial, their darkness emphasized by the scarce cutting light. At certain points in the baths, one cannot see beyond their immediate surroundings due to the darkness. These moments are about immersing one in the present, the moment is framed. Heavy walls and ceilings are made weightless by light. Light is used to structure the day to day life of the visitors and bathers in the spa. In the accomodations one is woken up by the sun streaming through the roof skylight. In the baths, light guides the bather to the next space.
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FACADE CONCEPT
VIEW IN THE CENTRAL SPACE
VIEW FROM THE ACCOMODATIONS
PLAN DETAIL 1:50
EAST ELEVATION 1:100
Annual Energy Use Estimate Report Summary Antonia Stanev
Project Designer
20509801
Student ID Number 811 m2 1014 m2 4000 m2
Total Net Floor Area Total Gross Floor Area Site Area
Estimated Total Annual Energy Use Energy Use by End-Use Space Heating Space Cooling Ventilation Water Heating Plug and Process Lighting Renewable Energy Generation
Window-to-Wall Ratio 0,40 Floor Area to Enclosure Ratio 0,71 Window Spec: U-value = 0.45 SHGC = 0.3 Daylight Fraction 0,14
108079 ekWh 15375 1268 6031 23767 1161 60478 0
Energy Use by End-Use Table
kWh kWh kWh kWh kWh kWh kWh
Space Cooling 1% Space Heating 14%
107 ekWh/m /year 107 ekWh/m /year
Energy Use Intensity (EUI)
2
EUI with Renewable Energy
Lighting 56%
Water Heating 22%
2
Estimated Global Warming Potential Nitrogen oxides (NOx) Sulphur dioxide (SO2) Carbon dioxide (CO2) Equivalent to CO2 emissions from
32 73 17326 34,1
kg kg kg cars
Ventilation 6%
Plug and Process 1%
EUI (kWh/m2/yr)
Energy Use Intensity Comparisons
500 450 400 350 300 250 200 150 100 50 0
482
Average Ontario Office Building [1] Average Ontario Cultural Industry [1]
395
Current Practice - Good [2] Current Practice - Better
275
Current Practice - Best Antonia Stanev's Project
200 125
158 107
118
Architecture 2030 Target - Today [3]
79
Architecture 2030 Target - 2015
39
Architecture 2030 Target - 2020
0
Architecture 2030 Target - 2025 Architecture 2030 Target - 2030
Notes: [1] EUI for Average Canadian Office Building is from Natural Resources Canada "Commercial and Institutional Building Energy Use Survey 2000" [2] EUI for Good, Better and Best Current Practice is based on current experience for this building type [3] More information about the Architecture 2030 Challenge can be found at http://architecture2030.org/
A LOOK AT THE ONDOL HEATING SYSTEM
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ONDOL AXONOMETRIC
1. Ah-goong-ee (Fire Pit) 2. Gorae- Route of Heat Flow 3. Gudeul- Floor, stores heat and releases it 4. Gaejeri- Deep channels that slow down the heat flow and prevent a backflow 5. Gultuk- Chimneys pulling out the smoke
VIEW OF THE BATHING JOURNEY
ONDOL SECTIONS
Ondol heating is a traditional korean heating system, of fire generated heat flowing beneath the floor. The chimneys are located at the opposite end of the fire pit, creating enough air pressure for the air and smoke to flow beneath the floor and outside. The temperature of the floor is stabilized by the concrete and ceramic tiles laid across the space. Heat is retained in the gathering space after the cooking in the kitchen is finished, keeping a comfortable temperature in the gathering space long after the meal. The smoke channels are spaced between concrete footings at every 3m, providing structural support for the walls and floor. This spacing allows for any additional systems needed to be run under the floor such as piping for water, to be placed in one of these channels.
FACADE DETAIL 1:50
SOUTH SECTION 1:100
CROSS SECTION/TEPIDARIUM AND SUDATORIUM 1:100
VIEW THROUGH THE GREENHOUSE ON A WINTER DAY
CROSS SECTION/ONDOL CHIMNEY 1:100
EAST SECTION 1:100
CONCRETE STRUCTURAL CONNECTIONS Structural Glazing Skylight Roof Assembly: 25mm large format cementitious roof Water barrier 250mm reinforced concrete NOTE: Roof tiles are introduced to hide the draining system of the roof and the skylight. A seamless look is desired.
Gutter System Foam Glass Insulation Light Gauge Z ceiling furring
NOTE: CONDITIONED LIVING SPACE
Lateral Load Steel Anchor Acting as a structural member connection, supporting the concrete tiles from gravity loads of the sloped roof. The anchor attaches the concrete tiles to the concrete roof.
Triple Glazing with Argon Fill Wall Assembly: 250mm Reinforced Concrete
Concrete Sill
Water Vapour Barrier 850mm Foam Glass Insulation Steel Framing 850mm Air Space 13mm Plasterboard
Floor Assembly: 30mm Polished Concrete Floor Hydronic Tubes 250mm Reinforced Concrete 500mm Rigid Foam Insulation Steel Furring Channels 13mm Plasterboard
2 piece Adjustable Veneer Ties These ties provide a connection for the volcanic rock in the baths to the reinforced concrete wall. They also transfer lateral loads as well as permit in-plane movement to accommodate differential movement.
NOTE: UNCONDITIONED WORK SPACE, UNINSULATED
Shear Load Connector Drainage Board
The shear load connectors are introduced between walls and slabs in order to transfer loads and allow for movement at the connection joints.
Water Vapour Barrier Gravel/Hardcore Backill Wood Blocks 550mm Soldier Piles at 2240mm O.C Insulation Layer Earth
Weeping Tile 500mmx 1500mm Reinforced Concrete Footing
EXTERIOR VIEW OF WALKWAY TO THE CENTRAL SPACE ARTIST STUDIO WALL DETAIL 1:20
NORTH ELEVATION 1:100