UT Zero-Energy House Layer House University of Tennessee, Knoxville Arc 572 I Spring 2008

Transcription

1 CONCEPT: LAYERING THE LAYER HOUSE IS A STUDY OF THE QUALITY AND CONDITIONS OF LIGHT AND SPACE WHICH ARE AFFECTED BY THE LAYERING OF OPERABLE ELEMENTS, FIXED STRUCTURAL ELEMENTS, AND MATERIALITY. THESE OPERABLE ELEMENTS ALSO FUNCTION AS PASSIVE HEATING AND COOLING STRATEGIES. THE IDEA OF LAYERING IS FOUND THROUGHOUT THE SCHEME, BOTH BY THE LAYERING OF SPACES THROUGH PHYSICAL BOUNDARIES, AS WELL AS THE BLENDING OF INTERIOR AND EXTERIOR SPACES. Concept diagram

2 architecture comfort zone market viability SUNCHART: SITE AT 35.8 DEGREES SITE PLAN 1:1000 PREVAILING WIND DIRECTIONS

3 architecture comfort zone market viability EXPLODED AXON CIRCULATION GRID ZONES

4 architecture comfort zone market viability engineering lighting hot water FLOOR PLAN

5 architecture comfort zone market viability engineering lighting hot water NORTHEAST ELEVATION

6 architecture comfort zone market viability engineering lighting hot water SOUTHEAST ELEVATION NORTHWEST ELEVATION

7 architecture comfort zone market viability engineering lighting hot water SOUTHWEST ELEVATION LONGITUDINAL ELEVATION

8 architecture comfort zone market viability engineering lighting hot water TRANSVERSE SECTION

9 architecture comfort zone market viability engineering lighting hot water FUNCTIONAL VOLUME SECTION

10 architecture comfort zone market viability engineering lighting hot water FUNCTIONAL VOLUME PLAN

11 architecture comfort zone market viability engineering lighting hot water FUNCTIONAL VOLUME EXPLODED AXON FUNCTIONAL VOLUME SCHEDULE

12 architecture comfort zone market viability engineering lighting hot water DETAIL SECTION

13 architecture comfort zone market viability engineering lighting hot water NORTHWEST ELEVATION

14 architecture comfort zone market viability kit of parts appliances energy balance STEEL I BEAM STRUCTURALLY INSULATED PANEL PRECAST CONCRETE SLABS STEEL H COLUMN GLASS SIP WALLS

15 architecture comfort zone market viability kit of parts appliances energy balance PRECAST CONCRETE SLABS VERTICAL LOUVERS HORIZONTAL LOUVERS FUNCTIONAL VOLUME MODULES FUNCTIONAL VOLUME

16 architecture comfort zone market viability CORTEN STEEL WOOD OPTIONS: TEAK LAMINATED BEECHWOOD FUNCTIONAL VOLUME

17 PRECAST CONCRETE FLOOR CANVAS LIGHT DIFFUSING FIXTURES STAINLESS STEEL WOOD OPTIONS: TEAK BEECHWOOD WENGEWOOD VENEER WALNUT VENEER

18 KITCHEN PERSPECTIVE DEN PERSPECTIVE BED PERSPECTIVE STORAGE PERSPECTIVE BEECHWOOD WENGEWOOD VENEER WALNUT VENEER

19 SHADING CONDITION: APRIL 25, 9 AM

20 SHADING CONDITION: APRIL 25, 12 PM

21 SHADING CONDITION: APRIL 25, 5 PM

22 engineering lighting hot water PHOTOVOLTAICS: PV MEMBRANE SOLID VOLUMES EVACUATED TUBES PRIMARY CIRCULATION THERMAL MASS CROSS AND STACK VENTILATION WATER COLLECTION

23 3 M 3 M SQUARE URBAN INFILL UNITS ROW HOUSE COURTYARD HOUSE POSSIBLE CONFIGURATIONS OF BASIC MODULE

24 ROW HOUSE UNITS

25 PLAN: COOLING STRATEGIES SECTION: COOLING STRATEGIES

26 PLAN: DAYLIGHTING SECTION: DAYLIGHTING

27 PLAN: HEATING STRATEGIES SECTION: HEATING STRATEGIES

28 PLAN: WATER COLLCTION SECTION: WATER COLLECTION

29 ENERGY REPORT: TYPICAL SUMMER CONDITIONS, DISPLAYING ALL ELEMENT GROUPS

30 ENERGY REPORT: EXTREME SUMMER CONDITIONS, DISPLAYING ALL ELEMENT GROUPS

31 ENERGY REPORT: TYPICAL SUMMER CONDITIONS, DISPLAYING TOTAL NET HEAT FLOW

32 ENERGY REPORT: EXTREME SUMMER CONDITIONS, DISPLAYING TOTAL NET HEAT FLOW

33 ENERGY REPORT: TYPICAL WINTER CONDITIONS, DISPLAYING ALL ELEMENT GROUPS

34 ENERGY REPORT: EXTREME WINTER CONDITIONS, DISPLAYING ALL ELEMENT GROUPS

35 ENERGY REPORT: TYPICAL WINTER CONDITIONS, DISPLAYING TOTAL NET HEAT FLOW

36 ENERGY REPORT: EXTREME WINTER CONDITIONS, DISPLAYING TOTAL NET HEAT FLOW

37 CISTERN SIZING CHART:

38 PHOTOVOLTAIC ESTIMATE

39 SHADING CRITERIA

40 SHADING CRITERIA