Ventilative cooling

Ventilative cooling is the use of natural or mechanical ventilation to cool indoor spaces.[1] The use of outside air reduces the cooling load and the energy consumption of these systems, while maintaining high quality indoor conditions. Ventilative cooling strategies are applied in a wide range of buildings and may even be critical to realize renovated or new high efficient buildings and zero-energy buildings (ZEBs) [2]. Ventilation is present in buildings mainly for air quality reasons. It can be used additionally to remove both excess heat gains, as well as increase the velocity of the air and thereby widen the thermal comfort range.[3] Ventilative cooling is assessed by long-term evaluation indices [4].Ventilative cooling is dependent on the availability of appropriate external conditions and on the thermal physical characteristics of the building.

Background

In the last years, overheating in buildings has been a challenge not only during the design stage but also during the operation. The reasons are: [5][6]

  • High performance energy standards which reduce heating demand in heating dominated climates. Mainly refer to increase of the insulation levels and restriction on infiltration rates
  • The occurrence of higher outdoor temperatures during the cooling season, because of the climate change and the heat island effect not considered at the design phase
  • Internal heat gains and occupancy behavior were not calculated with accuracy during the design phase (gap in performance).

In many post-occupancy comfort studies overheating is a frequently reported problem not only during the summer months but also during the transitions periods, also in temperate climates.

Potentials and limitations

The effectiveness of ventilative cooling has been investigated by many researchers and has been documented in many post occupancy assessments reports [7][8][9].The system cooling effectiveness (natural or mechanical ventilation) depends on the air flow rate that can be established, the thermal capacity of the construction and the heat transfer of the elements. During cold periods the cooling power of outdoor air is large. The risk of draughts is also important. During summer and transition months outdoor air cooling power might not be enough to compensate overheating indoors during daytime and application of ventilative cooling will be limited only during the night period. The night ventilation may remove effectively accumulated heat gains (internal and solar) during daytime in the building constructions [10]. For the assessment of the cooling potential of the location simplified methods have been developed [11][12][13][14]. These methods use mainly building characteristics information, comfort range indices and local climate data. In most of the simplified methods the thermal inertia is ignored.

The critical limitations for ventilative cooling are:

  • Impact of global warming
  • Impact of urban environment
  • Outdoor noise levels
  • Outdoor air pollution
  • Pets and insects
  • Security issues
  • Locale limitations

Existing regulations

Ventilative cooling requirements in regulations are complex. Energy performance calculations in many countries worldwide do not explicitly consider ventilative cooling. The available tools used for energy performance calculations are not suited to model the impact and effectiveness of ventilative cooling, especially through annual and monthly calculations [15].

Case studies

A large number of buildings using ventilative cooling strategies have already been built around the world [16][17][18]. Ventilative cooling can be found not only in traditional, pre-air-condition architecture, but also in temporary European and international low energy buildings. For these buildings passive strategies are priority. When passive strategies are not enough to achieve comfort, active strategies are applied. In most cases for the summer period and the transition months, automatically controlled natural ventilation is used. During the heating season, mechanical ventilation with heat recovery is used for indoor air quality reasons. Most of the buildings present high thermal mass. User behavior is crucial element for successful performance of the method.

Building components and control strategies

Building components of ventilative cooling are applied on all three levels of climate-sensitive building design, i.e. site design, architectural design and technical interventions . A grouping of these components follows [1] [19]:

  • Airflow guiding ventilation components (windows, rooflights, doors, dampers and grills, fans, flaps, louvres, special effect vents)
  • Airflow enhancing ventilation building components (chimneys, atria, venturi ventilators, wind catchers, wind towers and scoops, double facades, ventilated walls)
  • Passive cooling building components (convective components, evaporative components, phase change components)
  • Actuators (chain, linear, rotary)
  • Sensors (temperature, humidity, air flow, radiation, CO2, rain, wind)

Control strategies in ventilative cooling solutions have to control the magnitude and the direction, of air flows in space and time [1]. Effective control strategies ensure high indoor comfort levels and minimum energy consumption. Strategies in a lot of cases include temperature and CO2 monitoring [20]. In many buildings in which occupants had learned how to operate the systems, energy use reduction was achieved. Main control parameters are operative (air and radiant) temperature (both peak, actual or average), occupancy, carbon dioxide concentration and humidity levels [20]. Automation is more effective than personal control [1]. Manual control or manual override of automatic control are very important as it affects user acceptance and appreciation of the indoor climate positively (also cost)[21].The third option is that operation of facades is left to personal control of the inhabitants, but the building automation system gives active feedback and specific advises.

Existing methods and tools

Building design is characterized by different detailed design levels. In order to support the decision-making process towards ventilative cooling solutions, airflow models with different resolution are used. Depending on the detail resolution required, airflow models can be grouped into two categories[1]:

  • Early stage modelling tools, which include empirical models, monozone model, bidimensional airflow network models;and
  • Detailed modelling tools, which include airflow network models, coupled BES-AFN models, zonal models, Computational Fluid Dynamic,coupled CFD-BES-AFN models.

Existing literature includes reviews of available methods for airflow modelling. [9] [22][23][24][25][26][27]

IEA EBC Annex 62

Annex 62 ‘ventilative cooling’ was a research project of the ‘Energy in Buildings and Communities Programme (EBC)’ of the International Energy Agency (IEA), with a four-year working phase (2014–2018)[28]. The main goal was to make ventilative cooling an attractive and energy efficient cooling solution to avoid overheating of both new and renovated buildings. The results from the Annex facilitate better possibilities for prediction and estimation of heat removal and overheating risk – for both design purposes and for energy performance calculation. The documented performance of ventilative cooling systems through analysis of case studies aimed to promote the use of this technology in future high performance and conventional buildings [29]. To fulfill the main goal the Annex had the following targets for the research and development work:

  • To develop and evaluate suitable design methods and tools for prediction of cooling need, ventilative cooling performance and risk of overheating in buildings.
  • To develop guidelines for an energy-efficient reduction of the risk of overheating by ventilative cooling solutions and for design and operation of ventilative cooling in both residential and commercial buildings.
  • To develop guidelines for integration of ventilative cooling in energy performance calculation methods and regulations including specification and verification of key performance indicators.
  • To develop instructions for improvement of the ventilative cooling capacity of existing systems and for development of new ventilative cooling solutions including their control strategies.
  • To demonstrate the performance of ventilative cooling solutions through analysis and evaluation of well-documented case studies.

The Annex 62 research work was divided in three subtasks.

  • Subtask A “Methods and Tools” analyses, developed and evaluated suitable design methods and tools for prediction of cooling need, ventilative cooling performance and risk of overheating in buildings. The subtask also gave guidelines for integration of ventilative cooling in energy performance calculation methods and regulation including specification and verification of key performance indicators.
  • Subtask B “Solutions” investigated the cooling performance of existing mechanical, natural and hybrid ventilation systems and technologies and typical comfort control solutions as a starting point for extending the boundaries for their use. Based upon these investigations the subtask also developed recommendations for new kinds of flexible and reliable ventilative cooling solutions that create comfort under a wide range of climatic conditions.
  • Subtask C “Case studies” demonstrated the performance of ventilative cooling through analysis and evaluation of well-documented case studies.
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See also

References

  1. P. Heiselberg, M. Kolokotroni. "Ventilative Cooling. State of the art review". Department of Civil Engineering. Aalborg University, Denmark. 2015
  2. venticool, the international platform for ventilative cooling. “What is ventilative cooling?”. Retrieved June 2018
  3. F. Nicol, M. Wilson. "An overview of the European Standard EN 15251". Proceedings of Conference: Adapting to Change: New Thinking on Comfort. Cumberland Lodge, Windsor, UK, 9-11 April 2010.
  4. S. Carlucci, L. Pagliano. “A review of indices for the long-term evaluation of the general thermal comfort conditions in buildings”. Energy and Buildings 53:194-205 · October 2012
  5. AECOM “Investigation of overheating in homes”. Department for Communities and Local Government, UK. ISBN 978-1-4098-3592-9. July 2012
  6. NHBC Foundation. “Overheating in new homes. A review of the evidence”. ISBN 978-1-84806-306-8. 6 December, 2012.
  7. H. Awbi. “Ventilation Systems: Design and Performance”. Taylor & Francis. ISBN 978-0419217008. 2008.
  8. M. Santamouris, P. Wouters. “Building Ventilation: The State of the Art”. Routledge. ISBN 978-1844071302. 2006
  9. F. Allard. “Natural Ventilation in Buildings: A Design Handbook”. Earthscan Publications Ltd. ISBN 978-1873936726. 1998
  10. M. Santamouris, D. Kolokotsa. "Passive cooling dissipation techniques for buildings and other structures: The state of the art". Energy and Building 57: 74-94. 2013
  11. C. Ghiaus. "Potential for free-cooling by ventilation". Solar Energy 80: 402-413. 2006
  12. N. Artmann, P. Heiselberg. "Climatic potential for passive cooling of buildings by night-time ventilation in Europe". Applied Energy. 84 (2): 187-201. 2006
  13. A. Belleri, T. Psomas, P. Heiselberg, Per. "Evaluation Tool of Climate Potential for Ventilative Cooling". 36th AIVC Conference " Effective ventilation in high performance buildings", Madrid, Spain, 23-24 September 2015. p 53-66. 2015
  14. R. Yao, K. Steemers, N. Baker. "Strategic design and analysis method of natural ventilation for summer cooling". Build Serv Eng Res Technol. 26 (4). 2005
  15. M. Kapsalaki, F.R. Carrié. "Overview of provisions for ventilative cooling within 8 European building energy performance regulations". venticool, the international platform for ventilative cooling. 2015.
  16. P. Holzer, T. Psomas, P. O’Sullivan. "International ventilation cooling application database". CLIMA 2016 : Proceedings of the 12th REHVA World Congress, 22-25 May 2016, Aalborg, Denmark. 2016
  17. venticool, the international platform for ventilative cooling. “Ventilative Cooling Application Database”. Retrieved June 2018
  18. P. O’Sullivan, A. O’ Donovan. Ventilative Cooling Case Studies. Aalborg University, Denmark. 2018
  19. P. Holzer, T.Psomas. Ventilative cooling sourcebook. Aalborg University, Denmark. 2018
  20. P. Heiselberg (ed.). “Ventilative Cooling Design Guide”. Aalborg University, Denmark. 2018
  21. R.G. de Dear, G.S. Brager. "Thermal Comfort in Naturally Ventilated Buildings: Revisions to ASHRAE Standard 55". Energy and Buildings. 34 (6).2002
  22. M. Caciolo, D. Marchio, P. Stabat. "Survey of the existing approaches to assess and design natural ventilation and need for further developments" 11th International IBPSA Conference, Glasgow. 2009.
  23. Q. Chen. “Ventilation performance prediction for buildings: A method overview and recent applications”. Building and Environment, 44(4), 848-858. 2009
  24. A. Delsante, T. A. Vik. "Hybrid ventilation - State of the art review," IEA-ECBCS Annex 35. 1998.
  25. J. Zhai, M. Krarti, M.H Johnson. "Assess and implement natural and hybrid ventilation models in whole-building energy simulations," Department of Civil, Environmental and Architectural Engineering, University of Colorado, ASHRAE TRP-1456. 2010.
  26. A. Foucquier, S. Robert, F. Suard, L. Stéphan, A. Jay. "State of the art in building modelling and energy performances prediction: A review," Renewable and Sustainable Energy Reviews, vol. 23. pp. 272-288. 2013.
  27. J. Hensen "Integrated building airflow simulation". Advanced Building Simulation. pp. 87-118. Taylor & Francis. 2004
  28. International Energy Agency’s Energy in Buildings and Communities Programme, "EBC Annex 62 Ventilative Cooling", Retrieved June 2018
  29. venticool, the international platform for ventilative cooling. “About Annex 62”. Retrieved June 2018
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