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Buildings 2020

Buildings 2020. Center for Building Performance & Diagnostics Carnegie Mellon University. Volker Hartkopf, with input from David Archer, Ömer Akin, Khee Poh Lam, and Vivian Loftness. Meta Issues.

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Buildings 2020

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  1. Buildings 2020 Center for Building Performance & Diagnostics Carnegie Mellon University Volker Hartkopf, with input from David Archer, Ömer Akin, Khee Poh Lam, and Vivian Loftness

  2. Meta Issues To create a path from being environmentally effective through sustainability to engage the built environment in a “restorative activity” (term from Bill Reed) Is the present state of our natural system “good enough”? Center for Building Performance and Diagnostics, a NSF/IUCRC, and ABSIC at Carnegie Mellon

  3. Buildings as an integral part of a living system and positively co-evolving to continuously improve: Sun Water Air Soil Resources Of our Planetary System

  4. This means…. • Moving away from a totally human-centric view of the world, • Understanding the synergism between nature and human nature, • Appreciating the interconnectedness of the whole, • Using principles of living systems to approach our work • Seeing ourselves as continual learners and avoiding hubris, • Encouraging dialogue and asking deeper questions, and • Recognizing the role of spirit and love in everything we do.

  5. Financing, designing, engineering, constructing, operating, and managing buildings that grow out of and reflect the characteristics and conditions of their place, and are integral, value-adding members of the living systems of which they are a part. This requires wholistic systems thinking/integration, methods, practices, • Natural • Human-social • Economic • Policy • Ethical

  6. This means…. • Access to nature linking indoor and outdoor rooms in layers of environmental diversity, Regionalism with inspired responses to climate and culture, • Passive conditioning and innovation to celebrate the affordable abundance of nature for daylighting, ventilation, creating color, dynamics, free warmth, free cooling. • Ecological land-use and ‘whole life’ pedestrian neighborhoods supported by light rail and high speed rail communities of culture and commerce, • A balance off integrated, robust and flexible infrastructures and timeless, highly crafted places, • Shift from esoteric and ionic ‘sculpi-tecture’ to celebrations of nature and humanity.

  7. Financing, Design, Engineering and Commissioning All Stake holders, including policy-community-owner/occupant-facilities management-construction-key technologie(s) providers-representatives are integrated from early design/engineering stage in a team with financier/architect/engineering owner team.

  8. Assisted by • Integrated building information models (BIM) which are inter-operable (e.g., IFC compliant). Such models should support the “life cycle” processes of the building from conceptual design (e.g., building performance analyses) to building operations (e.g., operational controls and diagnostics) • Supply chain management techniques/processes • Analyzed best practices

  9. Assisted by the existence of • Plug & Play high performance enclosure sub-systems that balance exterior climate and weather forces with interior occupant and functional requirements to beneficially use daylighting, material ventilation passive heating and cooling, as well s generate energy (PV, solar thermal); harvest and purify water and regenerate soil • Modularized and pre-fabricated structural and interior components and subsystems to provide for flexibility, adaptability and closed-cycle material flows (up-cycling in industrial or agricultural nutrient streams (Michael Braungart))

  10. Plug & Play highly integrated, fabricated, packaged and miniaturized distributed, multi-modal energy generation, conversion and conditioning subsystems. • Plug & Play sensing, actuating and control subsystems to operate the whole system (enclosure, energy, HVAC, lighting, etc.) effectively (user comfort, environment, energy, and water). • Plug & Play diagnostic systems (integrated with above) utilizing building performance modeling based on scientific (physics, biology, chemistry) and engineering principles.

  11. Operation, Long Term Maintenance, and Continuous Commissioning • Integrated transdisciplinary service contracting supported by advanced sensing, actuating and control technology with automated data storage, communication mining and meaningful reporting to continuously • Assessing the system’s performance vis à vis • Human comfort/productivity, ecological, environmental effectiveness (sun, water, air, soil), energy, economics.

  12. Diagnosing the systems requirements for maintenance, adjustments, and repair (preventative). • Integrated long-term learning from the actual performance -in the field- of the advanced, fabricated plug & play materials, components, subsystems, and systems to inform the entire industry and enable collective competence in “restorative practices”.

  13. Examples of Breakthrough Technologies from the HCII • Integrating and packaging multiple appropriate sensors with local intelligent and networking capability to measure indoor environmental parameters • Developing methods to engineer a system of personalized environmental monitoring sensors that are user transparent, ergonomically wearable objects. • Developing a system of communication to integrate the sensors into existing building information systems, architectural features, and engineered building components and systems. • Developing a system of algorithms for decision-making on collected information.

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