Primary Energy Consumption

‘Passivhaus’ Standard is Not Enough in New Building Projects !

2013-09-10:  Recently, much ado has been made in the technical press about a New Multi-Storey Office Block in Vienna which has achieved the German ‘Passivhaus’ (Passive House) Standard

Multi-Storey 'RHW.2' Office Block in Vienna, Austria

Is There A Problem ??   Yes !!

1.   It takes approximately 3 Years of Building Occupation, by ‘real’ people, before the actual performance of a building can be properly monitored and reliably shown.  The building is still ‘drying out’ for the first year.  It takes at least one to two years of running the complex technologies and systems in today’s buildings … training people how to operate them efficiently and effectively … and fine-tuning and de-bugging as you go along … before everything begins to work together, as originally intended during the building design stage.  Then, if all goes well … in the third year of occupation, the careful (i.e. accurate and reliable) monitoring of ‘real’ building performance, by means of portable measuring devices and devices installed within the construction, can commence.

So … what exactly has achieved the German ‘Passivhaus’ (Passive House) Standard … the design intent for the building, or the building’s ‘real’ performance ???

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2.   Much more fundamentally … achieving this Standard is a good starting point … but in a new building project … It Is Not Enough !

A.  Energy Conservation and Efficiency Burden Sharing by Different Building Types

Separate strategies are required to greatly improve the energy performance of:

  • existing buildings … onto which many energy efficiency measures can be successfully grafted, but it will be difficult work and will certainly not be cheap ;
  • buildings of historical, architectural or cultural importance … the integrity of which must be protected ;   and
  • new buildings and facilities … which must therefore carry the major burden.

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B.  Paradigm for New Buildings – A ‘Positive Energy’ Return + Assured Building User Comfort

Primary Energy Consumption should be less than or equal to 15 kWh/m2/yr.

And …

Renewable Energy and Heating Systems should contribute a reliable quantity of energy, per year, which covers the following:

i)   the Building’s/Facility’s Primary Energy Consumption ;

ii)  an Energy Efficiency Degradation Factor which takes account of the degradation in energy efficiency …

(a)  normally expected during the life cycle of renewable energy and heating systems installed in the building.  The rate of degradation will depend on the quality of maintenance and servicing ;   and

(b)  caused by wasteful patterns of building management and/or use ;

iii) the energy consumed by Private Transport associated with the building or facility ;

iv) an Energy Return to an Intelligent District, Local or Regional Grid exceeding, by a multiple of 3 (three), the total energy consumed by the Building/Facility (including its Energy Efficiency Degradation Factor) and any associated Private Transport.

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Notes:

Primary Energy includes the energy required to generate, transmit and distribute electricity, as well as energy directly consumed on site.

User Thermal Comfort = Air Temperature + Mean Radiant Temperature + Air Humidity + Air Velocity, i.e. draughts (ISO 7730).

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And interestingly enough … on the Passivhaus WebSite (German language version)www.passivhaus.de/passivhaus-informationen/vom-passivhaus-zum-plusenergiegebaeude.html … this is now the thinking there also !!

Should have been happening 10 years ago !

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SDI Practice Announcement – New 32 Storey Hotel in China

2013-04-02:  Sustainable Design International Ltd. (SDI) is pleased to announce that its Managing Director, C.J. Walsh, has been invited to be ‘Project Design Architect’ / ‘Design Professional in Responsible Charge’ for a New 32 Storey Hotel in Yunnan Province, People’s Republic of China (PRC).

He will have responsibility for the Project’s Architectural Concept Design and General Schematic Design … including the overall architectural character and profile of primary exterior surfaces.

Project Approximate Value = € 65 Million (Euros) … excluding interior design, finishes and furnishing (which could end up doubling, or even tripling, the overall project value).

Sustainable Design International Ltd.  maintains a strict practice policy of Client Confidentiality.

[ If this Type of Professional Design Service Appeals to You, or Your Organization – Contact Us Immediately ! ]

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2012 ‘Understanding China’ Policy Briefing Friends of Europe & EuroChambres

An estimated One Billion People will be living in China’s cities by 2030.  This large-scale and very rapid urbanization demands that a sustainable transformation of their urban built, social, economic and institutional environments commences Today – not at some notional point in a far distant future.

Furthermore … replicating a European approach to sustainable design and construction in other regions of the world is doomed to failure.  Urban Transformation in China must be adapted to Local Geography, Climate, Climate Change, Social Needs, Cultures, Economy, and Local Severe Events (e.g. earthquakes, flooding).  With European support and collaboration … China must, and will, find its own way.

Greening China's Cities of Tomorrow (2012) - Report CoverGreening China’s Cities of Tomorrow (Spring 2012)

Click the Link Above to read and/or download a PDF File (4.42 Mb)

Report on a One-Day China Advisory Council Roundtable, co-organized by Friends of Europe and EuroChambres, which was held in Brussels on 8 March 2012.  This event was part of an ‘Understanding China’ Programme (mid-2009 to mid-2012), co-funded by the European Commission.

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2013 Asian Development Bank (ADB) Guidebook: ‘Increasing Climate Change Resilience of Urban Water Infrastructure’ 

This Guide describes a practical approach to bridge the gap between theoretical analyses of climate change impacts and the planning decisions that need to be made by city authorities and utility managers to increase climate change resilience of the water sector in the city of  Wuhan, Hubei Province, People’s Republic of China (PRC).  It focuses on answering the questions currently being asked by city planners and managers all over the world, as follows:

  • What changes might be caused by climate change ?
  • How will these changes affect services and utilities ?
  • What can we do now to prepare for them ?

The long lead time required to plan, finance, build, and commission city infrastructure facilities means that decision makers cannot wait for more detailed data on the effects of future climate change, especially those relating to local circumstances, but must make investment decisions based on what is known now and what can be readily predicted.  An important principle in this kind of ‘robust’ decision-making is provided by the  Intergovernmental Panel on Climate Change (IPCC)  tenet that adaptation investments, which move a city’s infrastructure toward sustainable development (such as providing safe drinking water and better sanitary conditions), are justifiable even without climate change.

This Guide is arranged in clear steps to provide direction and information for similar exercises in other areas.  Having grown out of a specific locality and its needs, the principles and solutions developed in this guide are founded on real world situations and problems …

ADB Guidebook: 'Increasing Climate Change Resilience of Urban Water Infrastructure' (2013) - Cover PageIncreasing Climate Change Resilience of Urban Water Infrastructure (ADB, 2013)

Click the Link Above to read and/or download a PDF File (2.31 Mb)

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***  THIS TALL BUILDING IN YUNNAN PROVINCE  &  SIMILAR COMPLEX ARCHITECTURAL PROJECTS  ***

Working within the professional constraints of ‘client confidentiality’ … it is possible to have a general discussion about current building design, construction and operation issues in an international sector which is operating, more and more, beyond national borders … without adequate, or very often any, national and local regulation.  By ‘regulation’, I mean a flexible system of building-related legislation which is operated in conjunction with mandatory and effective technical control.

In order to cope with today’s complex built environment and the enormous variation in the size and scale of construction projects … a ‘flexible’ mix of functional, performance and prescriptive legal requirements is the sharpest and most appropriate instrument.

And you can forget the hype about performance-based building codes coming out of the USA … hot air, and much ado about little !

Of course, the biggest issue of all is the competence of those individuals who work in Authorities Having Jurisdiction (AHJ’s), i.e. technical controllers.  Even in the most developed economies of the world … there are many occasions when the level of individual incompetence in an AHJ is astounding … and institutional arrangements within the AHJ itself are a mess, i.e. the AHJ is not fit for purpose.

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1.  Sustainable Design – Design Process Efficiency & Proper Preparation for Construction

A tremendous amount of waste is associated with and generated by the processes of conventional building design, construction and operation.  There is a more up-to-date and efficient way of doing things … an essential way for Sustainable Design … and it’s called Building Information Modelling (BIM) !

Furthermore … consider, for a moment, just the initial list of Specialist Consultants who will be engaged directly by the Chinese Client when the project’s conceptual design has reached a sufficiently developed stage.  How can all of these individuals and organizations – listed in the revised and agreed Project Design Agreement – obtain accurate and reliable ‘real time’ information about the rapidly evolving project from a central design library / information database … then feed their new work back into the centre without unnecessary delay ?   How, next, can everyone else who needs to know, be updated with the new design input … again, without delay ?   And perhaps, these consultants may also be based in different countries … working in very different time zones …

  • Building Information Modelling (BIM) Consultant
  • Local Design Institute (LDI) … a local architectural practice which will produce the project’s working drawings, handle local spatial planning and building code approvals, carry out site inspections, and deal directly with construction organization(s), etc., etc.
  • Interior Design Consultant
  • Traffic / Parking Analysis Consultant
  • Curtain Wall Consultant (Curtain Wall, Skylights & Special Roof Structures)
  • Retail Market Analysis Consultant
  • Landscape Design Consultant
  • Quantity Surveying & Cost Estimating Consultant
  • Furniture Design Consultant
  • Geotechnical, Civil Engineering & Structural Engineering Consultant (including structural performance under fire and earthquake conditions, resistance to fire-induced progressive damage and disproportionate damage … and also including climate resilience)
  • Acoustic & Audio-Visual Design Consultant
  • Mechanical, Electrical & Plumbing (MEP) Engineering Consultant
  • Integrated Building Automation & Management / Telecom / Security / Networking Consultant
  • Fire & Life-Safety Engineering Consultant
  • Water Feature Consultant
  • Wind Tunnel Test Consultant
  • Kitchen Equipment and Layout Design Consultant
  • Art, Artefact and Accessories Consultant & Procurement Services for Art, Artefacts, and Accessories
  • Tenant Storefront Design Consultant
  • Helicopter Landing Pad Design Consultant
  • Universal Design / Accessibility for All Consultant [including access to the building, electronic, information and communication technologies (EICT’s), and services offered at the hotel … and including fire safety, protection and evacuation for all]

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2.  The ‘Design Professional in Responsible Charge’ !

The Project Design Agreement requests that the Client receive advice on who might be the different Specialist Consultants listed above.  In addition, it will be necessary to demarcate the boundaries within which each Consultant will operate … and, where appropriate, to prescribe a design performance target (see below) for each speciality … which must be ‘realized’ in the completed and occupied building !

Recalling the many previous posts, here on this Technical Blog, concerning NIST’s 2005 & 2008 Recommendations on the 9-11 World Trade Centre Building Collapses in New York City‘somebody’ must ensure that the many individuals and organizations listed above – members of the Larger (2nd Stage) Design Team – use consistent design data and assumptions … must co-ordinate design documents and specifications to identify overlaps and eliminate gaps … must serve as ultimate liaison between the Client, the Local Design Institute, AHJ officials, and the Construction Organization(s) … and must ensure that everybody is on the same communication wavelength, and working towards the same objective in a trans-disciplinary manner.

That ‘Somebody’ … the Design Professional in Responsible Charge … must be the Project Design Architect !

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3.  Some Sustainable Design Performance Targets

Actual construction and building user performance shall be carefully (i.e. reliably and precisely) monitored … and independently verified …

A.   Basic Functional Requirements … the Building shall comply with the Basic Requirements for Construction Works – elaborated in Annex I of European Union (EU) Regulation No.305/2011 of the European Parliament and of the Council, of 9 March 2011, laying down Harmonized Conditions for the Marketing of Construction Products and Repealing Council Directive 89/106/EEC.

See my Post, dated 2011-09-13 … https://www.cjwalsh.ie/2011/09/new-eu-construction-product-regulation-3052011-halleluiah/

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B.   Good Indoor Air Quality (IAQ) … Two high-level performance indicators have been developed with the aim of protecting Human Health, and are both now referenced in International Standard ISO 21542: ‘Building Construction – Accessibility & Usability of the Built Environment’

      –   Radon Activity (incl. Rn-222, Rn-220, RnD) in a building should, on average, fall within the range of 10 Bq/m3 to 40 Bq/m3, but shall at no time exceed 60 Bq/m3 ;

      –   Carbon Dioxide (CO2) Concentrations in a building should not significantly exceed average external levels – typically within the range of 300 parts per million (ppm) to 500 ppm – and shall at no time exceed 800 ppm.

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C.   Energy Conservation & Efficiency + A ‘Positive Energy’ Return + Assured Building User Thermal Comfort

See my Post, dated 2013-09-10 … https://www.cjwalsh.ie/2013/09/passivhaus-standard-is-not-enough-in-new-building-projects/

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D.   Project-Specific Sustainable Fire Engineering Design Objectives

See my Post, dated 2014-04-20 … https://www.cjwalsh.ie/2014/04/sustainable-fire-engineering-design-targeting-mrv/

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BER Certificates, Energy Efficiency & Climate Change (II)

2009-02-23:  The World Business Council for Sustainable Development (WBCSD) has identified buildings as one of the five main users of energy where ‘megatrends’ are needed to transform global energy efficiency in the immediate short term, and so meet the daunting challenge of Climate Change Adaptation.  They account for 40% of primary energy (primary energy includes the energy required to generate, transmit and distribute electricity, as well as energy directly consumed on site) in most developed countries, and consumption is rising. 

                         … 2007 WBCSD Energy Efficiency in Buildings (EEB) Project

 

 

If you find that you are not responding emotionally to that … please leave your computer immediately and take a cold shower !   When you return, check out how far adrift Ireland is – even on paper – in meeting its legally binding 1997 Kyoto Protocol (UNFCCC) responsibilities.  After 2012, the European Union’s 2020 Targets will be in a different league altogether.

 

Let there be do doubt, therefore, that over the next few years … nothing less than a complete cultural shift will be necessary throughout the European Construction Sector – and this very much includes Ireland – beginning with all research and design disciplines and extending right across to any person who works on a construction site or has any part to play in managing, maintaining or servicing a building.

 

 

 

Burden Sharing in the Built Environment

 

Separate Energy Efficiency Strategies will be required to vastly improve the energy performance of:

         existing buildings … onto which many energy efficiency measures can be successfully grafted … but they will not be cheap, and they will not be 100% effective ;

         buildings of historical, architectural or cultural importance … the integrity of which must be protected ;   and

         new buildings, which must therefore carry the major burden.

 

In addition … if we fully value the Agricultural Industry in Ireland, the burden to be carried by New Buildings may have to be far heavier.

 

 

 

Suggested Building Energy Efficiency Targets in Ireland to 2020

 

From the Beginning of 2012, i.e. after an Essential Transition Period involving extensive re-education and up-skilling, accompanied by ‘attractive’ incentives …

         Require all New Buildings to achieve a Minimum Building Energy Rating (BER) of ‘A1’ … indicating a Primary Energy Consumption less than or equal to 25 kWh/m2/yr.  And require 40% of Primary Energy Consumed to be, directly or indirectly, from Renewable Energy Sources ;

         Require all Existing Buildings to achieve a Minimum Building Energy Rating (BER) of ‘B1’ … indicating a Primary Energy Consumption less than or equal to 100 kWh/m2/yr.  And require 15% of Primary Energy Consumed to be, directly or indirectly, from Renewable Energy Sources.  Retain Incentive Measures to achieve better performance with regard to energy efficiency and/or renewable energies ;

         Require Buildings of Historical, Architectural or Cultural Importance to achieve a Minimum Building Energy Rating (BER) of ‘C1’ … indicating a Primary Energy Consumption less than or equal to 175 kWh/m2/yr.  Retain Incentive Measures to achieve better energy efficiency performance.  No legal requirements or incentives with regard to Renewable Energies should apply to Buildings of Historical, Architectural or Cultural Importance.

 

From the Beginning of 2015

         Require all New Buildings to be ‘Positive Energy Buildings’ (see below) ;

         Require all Existing Buildings to achieve a Minimum Building Energy Rating (BER) of ‘A2’ … indicating a Primary Energy Consumption less than or equal to 50 kWh/m2/yr.  And require a Positive Energy Contribution of 25 kWh/m2/yr to be from renewable Energy Systems installed in the building ;

         Require Buildings of Historical, Architectural or Cultural Importance to achieve  a Minimum Building Energy Rating (BER) of ‘B1’ … indicating a Primary Energy Consumption less than or equal to 100 kWh/m2/yr.  Retain Incentive Measures to achieve better energy efficiency performance.  No legal requirements or incentives with regard to Renewable Energies shall apply to Buildings of Historical, Architectural or Cultural Importance.

 

 

 

‘Effective’ Technical Control of Construction & Post-Occupation Buildings

 

Any proposed Building Energy Efficiency/Conservation and Renewable Energy Improvements must take place in a legal environment of stringent control during construction (by competent Local Authority Building Controllers and/or Independent Technical Controllers) and rigorous post-construction energy performance monitoring (using Long Wave Infra-Red Thermal Imagery, in conjunction with building roof and external wall Air Seepage Tests).  Observation of post-occupation building energy performance will also be necessary.  Introduce mandatory 5-Yearly Energy Surveying of Buildings.

 

 

 

The Paradigm for New Buildings – A ‘Positive Energy’ Return

 

Primary Energy Consumption is less than or equal to 15 kWh/m2/yr.  Renewable Energy & Heating Systems then contribute a reliable quantity of energy, per year, which covers the following:

         the Building’s Primary Energy Consumption ;

         an Energy Efficiency Degradation Factor which takes account of the degradation in energy efficiency normally expected during the life cycle of renewable energy and heating systems installed in the building (the rate of degradation will depend on the quality of maintenance and servicing) … and caused by wasteful patterns of building management and/or use ;

         the energy consumed by Private Transport associated with the building ;

         an Energy Return to an Intelligent District or Regional Grid exceeding, by a whole number multiple determined by reference to local conditions, the total energy consumed by the Building (including its Energy Efficiency Degradation Factor) and any associated Private Transport.

 

Uniquely, this more practical elaboration of the innovative concept of Positive Energy Buildings considers life cycle energy efficiency degradation.

 

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