Development of an energy evaluation methodology to make multiplepredictions of the HVAC&R system energy demand for office buildings
May 2014 - PDF 4.88MB
By: Jinkyun Choa, Seungho Shina, Jonghurn Kimb, Hiki Hong
HVAC&R systems are the most energy consuming building services, representing approximately half of the final energy use in the building sector. Despite their significant energy use, there is a lack of a consistent and homogeneous framework to efficiently guide research, mainly due to the complexity and variety of HVAC&R systems, but also to insufficient rigor in their energy analysis. Quantifying the energy consumption characteristics of HVAC&R system is complicated, because the energy savings provided by this system depend on various factors. This research evaluates energy consumption characteristics of HVAC&R systems, with the aim of establishing a common idea for the analysis of building energy efficiency. The objective of this study is to develop an energy evaluation methodology and a simple simulation program that may be used by engineers and designers to assess the effectiveness and economic benefits of HVAC&R systems. Our approach deals with the concept of HVAC&R system energy use aggregation levels that are composed of subsystems. To carry out a techno-economical estimation of HVAC&R systems considering different types of subsystems, the matrix combination analyzed, and a total of 960 HVAC&R systems can be implemented for a large-scale office building. The methodology of energy analysis that was carried out in this study highlights how to plan and design toward utilizing the most effective HVAC&R systems.
Development of an energy evaluation methodology to make multiplepredictions of the HVAC&R system energy demand for office buildings
Fulfillment of net-zero energy building (NZEB) with four metrics in a single family house with different heating alternatives
September 2013 - PDF 2.13MB
By: Ayman Mohamed, Ala Hasan, Kai Sirén
This study aims to investigate the fulfillment of four Net Zero Energy Building (NZEB) balances, NZEB-PE, NZEB-site, NZEB-emission and NZEB-cost, considering the four metrics of primary energy (PE), site energy, CO2-eqemissions and energy cost, respectively, using weighting factors based on Finnish and international reference data. The study analyzes five conventional energy systems and seven biomassbased standalone and shared combined heat and power (CHP) systems. These systems are connected to a single family house located in Helsinki, Finland, with two energy efficiency levels: a standard house and a passive house, simulated by Trnsys software. The annual balance of the import and export of the operational thermal and electrical energies is applied. The simulated results indicate that the NZEB-emission, NZEB-PE, NZEB-cost, and NZEB-site are arranged in that order according to the ease of fulfilling the annual balance. Making the house high in thermal energy efficiency (or adding solar thermal collectors) for all the studied systems is a step towards achieving NZEB-PE, NZEB-cost, and NZEB-site. On the contrary, achieving the NZEB-emission by the shared CHPs connected to the standard house is easier than the passive house. The NZEB balance is more attainable by the shared CHPs than the standalone CHPs.
The NZEB-PE is easier to achieve using the international factors than using the Finnish PE factors.
Fulfillment of net-zero energy building (NZEB) with four metrics in a single family house with different heating alternatives
Solar Steam Cooking Made Possible in the Treacherous regions on Ladakh
January 2013
By: Thermax Solar
Publisher: EQ International April 2013 Issue, Page 57
Solar Thermal Marking New Frontiers
January 2013
By: Thermax Solar
Publisher: EQ International March 2013 Issue, Page 61
Nearly-zero, Net zero and Plus Energy Buildings – How definitions & regulations affect the solutions
December 2012 - PDF 0.39MB
By: Karsten Voss, Igor Sartori, Roberto Lollini
The topic of Zero Energy Buildings (ZEBs) has received increasing attention in recent years, up to inclusion in strategic energy policy papers in several countries. However, despite the emphasis placed on the goals, the various ZEB definitions applied mostly remain generic and are not yet standardised.
Nearly-zero, Net zero and Plus Energy Buildings – How definitions & regulations affect the solutions
Photovoltaics and Zero Energy Buildings: A New Opportunity and Challenge for Design
October 2012 - PDF 1.21MB
By: Alessandra Scognamiglio and Harald N. Røstvik
Starting from the end of 2020, all new buildings will have to be Nearly Zero Energy Buildings (Nearly ZEBs—ED 2010/31/EU recast). This new ‘energy paradigm’ might be a revolution for architecture and for Photovoltaics (PV) too, but there are both cultural and technical obstacles to overcome. There is a need to re-think the way buildings are designed (integrating renewables for being ZE). There is a need to re-think the way PV is designed in buildings. PV will be gaining an increasing relevance in the ZEBs design, thanks to its features and potentialities (suitability for any kind of energy demand of the building, easiness of building integration, cost). In a ZEB scenario, PV is very suitable for generating energy, ‘on site’ and ‘at site’; this enlarges the perspective of use of PV from the architectural scale to a wider scale, including the space close to the building or even to the urban and landscape scale. In such a new context, the existing research on the relationships between PV and architecture, focusing mainly on the way the PV components are used in relation to the envelope (Building-integrated PV/Building-added (Attached) PV), is no longer sufficient. The authors envision possible formal results, opportunities and challenges, for the use of PV in ZEBs, as well as new research issues for the future relationships between PV and ZEBs from the architecture and landscape design point of view. Copyright © 2012 John Wiley & Sons, Ltd.
Net zero energy buildings: A consistent definition framework
February 2012 - PDF 0.68MB
By: Igor Sartori, Assunta Napolitano, Karsten Voss
The term Net ZEB, Net Zero Energy Building, indicates a building connected to the energy grids. It is recognized that the sole satisfaction of an annual balance is not sufficient to fully characterize Net ZEBs and the interaction between buildings and energy grids need to be addressed. It is also recognized that different definitions are possible, in accordance with a country’s political targets and specific conditions. This paper presents a consistent framework for setting Net ZEB definitions. Evaluation of the criteria in the definition framework and selection of the related options becomes a methodology to set Net ZEB definitions in a systematic way. The balance concept is central in the definition framework and two major types of balance are identified, namely the import/export balance and the load/generation balance. As compromise between the two a simplified monthly net balance is also described. Concerning the temporal energy match, two major characteristics are described to reflect a Net ZEB’s ability to match its own load by on-site generation and to work beneficially with respect to the needs of the local grids. Possible indicators are presented and the concept of grid interaction flexibility is introduced as a desirable target in the building energy design.
Europe Asia Solar Cooling Gains Traction
January 2012
By: Bärbel Epp
Editor: Solarthermalworld
Publisher: Solarthermalworld
Large Japanese and Chinese companies have recently taken a greater interest in solar cooling. The photo shows an installation by Chinese company Jiangsu Huineng New Energy Technology (Huin), which started supplying solar cooling systems this year. New system kits help drive down costs, although investments in sorption chillers are still higher than for compression chillers. After the Intersolar Europe conference in Munich, Germany, and its dedicated solar cooling session, Uli Jakob, Vice President of the German sorption chiller association Green Chiller, noted: “Solar cooling was one of the highlights of the conference.”

  • PDF 0.03MB
Europe Asia Solar Cooling Gains Traction
Keeping Cool with the Sun
Latest Developments on Solar Cooling and Task 48 Short Presentation
January 2012 - PDF 1.36MB
By: Daniel Mugnier (TECSOL) & Uli Jakob (SOLEM Consulting)
Publisher: International Sustainable Energy Review
Worldwide, the energy consumption required for cold and air conditioning is rising rapidly. Usual electrically driven compressor chillers (split units) have maximum energy consumption in peak-load periods during the summer. In the last few years in Southern Europe this has regularly led to grids working to maximum capacity and blackouts. In recent years, the sales figures of split units with a cooling capacity range of up to 5KW have risen rapidly.

www.internationalsustainableenergy.com
Keeping Cool with the Sun