Climate - Engineering Physics - Architecture - Sustainability Natural ventilation Optimal use of daylight Matthias Schuler Using Using natural natural cooling couling resources Multifuncti onal shading device Transsolar Energietechnik GmbH Stuttgart Munich New York www.transsolar.com Sustainability - Why? Physical Effects Project examples Deutsche Post, Bonn Parcela 15, Madrid Hybrid Looped Project, Beijing Novartis Campus, Basel Design School, Essen A Cloud for Qatar New Souk Overview 1
Energy consumption Germany 2002 46% At least 46% of the energy consumption is connected to buildings Climate engineer Client Architect HVAC engineer Structural engineer You can do it only in a Design Team 2
Year of foundation: 1992 Managing directors: M. Schuler, Prof. Dr. T. Lechner, P. Voit T. Auer, S. Holst, V. Bleicher Turnover 2004: 3.5 Mio Number of employees and their specialist areas: Number of employees: 1 1992 35 2004 Qualification : Mechanical engineer, Physicist, Industrial Process engineer, Management expert, Project locations: Germany 50% other Europe 20% Asia 10% North America 20% Transsolar overview Be closer to your clients and architects Stuttgart (28) New York (1-2) München (6) 2003 - extending from Stuttgart 3
Büros 1. OG Büros 2. OG Büros 3. OG Büros 4. OG Büros 5. OG Doppelfassade 1. OG Doppelfassade 2. OG Doppelfassade 3. OG Doppelfassade 4. OG Doppelfassade 5. OG Umgebungstemperatur Air temperature Radiation temperature Solar radiation Air velocity Humidity Activity Clothing Tageslichtverteilung Frischluftversorgung Solarstrahlung (Wärme / Licht) Wärm eabgabe durch A bstrahlung Luftbewegung Klimadaten: - Lufttemperatur - Luftfeuchte Unzuf ri edene Pe rs one n ( PPD) i n % 45 40 35 30 25 20 15 10 Konventionelle Kühlkonzepte mit mechanischer Kühlung Thermischer Komfort im Raum bei verschiedenen Temperaturen der Oberflächen im Raum Bürotätigkeit, Leichte Arbeitskleidung Keine Direktstrahlung, Luftgeschw. 0.15 m/s, abs. Luftfeuchte 11 g/kg Predicted Percentage of Dissatisfied (PPD) nach Prof. O.Fanger Natürliche Lüftungskonzepte mit regenerativer Kühlung Oberflächentemperatur 26 C 25 C 24 C 23 C 22 C 21 C Comfort evaluation DIN/ISO 7730 5 0 23 24 25 26 27 28 29 30 31 32 33 Lufttemperatur im Raum in C Thermal Comfort influences Professional Design Tools Dynamic Thermal Simulation: dynamic thermal behaviour of a building depending on: thermal mass, weather conditions, internal and external gains, solar radiation, condensation problems energy consumption and power demand comfort evaluation Temperatur in C Büros und der Doppelfassade Süden 45 40 35 30 25 20 15 10 0 6 12 18 24 30 36 42 48 Zeit in Stunden Computational Fluid Dynamics, CFD calculation and visualisation of air flows inside and outside a building details of natural convection systems, stratification effects comfort aspects Daylighting Analysis by Simulation: calculation and visualisation of luminance and illuminace distributions optimisation of glazing and shading quality, shading details for complex geometry's both in spatial and temporal resolution analysis of contrast ratios and glare in the visual field visual comfort aspects 4
Physics Conduction 5
Energy transport through a material Depending on: material temperature difference density heat capacity conductivity Conduction Convection 6
Thermal driven air movement Depending on: air temperature and humidity surface temperature air velocity Convection Stratification 7
Stabile layering of air with different conditions Depending on: air density air temperature warm air is lighter than cold air humidity humid air is lighter than dry air air velocity Stratification Evaporation 8
Phase change of a material form liquid to vapor under energy input Depending on: humidity difference air temperature water temperature movement of water surface air velocity dew point of room air if below dew point -- condensation Evaporation Transmission/Reflection 9
Radiation transport through a material Depending on: material geometry wave length reflection coefficient extinction coefficient refraction index form, thickness UV, visible, IR Transmission/Reflection Heat-Radiation 10
Heat radiation happens between two bodies of different temperature 50% of heat transport is radiation Depending on: material temperature difference emission coefficient Heat-Radiation Concept and project examples 11
Deutsche Post, Bonn Architect: Murphy / Jahn, Chicago Structure: Werner Sobek Ingenieure, Stuttgart Energy Concept: Transsolar, Stuttgart MEP Consultant: Brandi Consult, Berlin Breathing in the wind - Deutsche Post Tower, Bonn ATH2002 Deutsche Post from North-East 12
Looped Hybride Buildings Steven Holl Architects, New York Regeneration to keep the system in balance 13
Parcela 15, Madrid, AUIA Architects West facade of social housing project with solar exhaust chimneys Novartis Campus, Building WSJ 124, Basel, Gehry Partners LLP 14
Design Team: Architect: Sanaa / Heinrich Böll Structural engineer: Bollinger + Grohmann Technique coordination: Transplan Climate engineer: Transsolar MEP consultant: Winter Ingenieure Building physics: Horstmann Berger Design School Zollverein, Essen Architect: ng architects, Beirut Energy concept: Transsolar, Stuttgart MEP: Barbanel, 15
Cloud event Heat and vapor supply AHU Solar heat production shadow 16
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