Measuring office fit-out changes to determine recurring embodied energy in building life cycle assessment

Purpose – The purpose of this paper is to quantify and profile the indicative amount of retrofits in office buildings as a necessary step in quantifying the recurring embodied energy in office buildings. Buildings are a major source of energy usage and emissions, and office buildings are a significant contributor to this situation. Life cycle assessments in this area have tended to neglect the potentially large impact arising from recurring embodied energy associated with office fit-out – which is often akin to a short-term consumable rather than a long-term durable in many multi-storey buildings. Design/methodology/approach – This study used building permit data from the Melbourne Central Business District (n = 986) over the period 2006-2010 (inclusive) to quantify the number of retrofits and related trends. Building on this, a small number of targeted case study buildings were used to probe specific issues in profiling trends associated with high-frequency trends arising from the main sample. Findings – The data show that the number of retrofits varies according to location, grade, size and the age of buildings. Using the case study data, there is initial evidence to suggest that between 46 and 70 per cent of the floors in a high-rise office building will undergo retrofit in a five-year period. Further research should apply these data to recurring energy modelling for office buildings. Research limitations/implications – One limitation which applies to this study is that the research is limited to a defined geographical area in one Australian city, Melbourne. Secondly the study covers a specific period, and the number of retrofits may be affected negatively or positively depending on the prevailing market conditions. Practical implications – This paper raises important questions in respect of life cycle carbon emissions in the context of prevailing trends to shorter lease terms and practices around fit-out. Originality/value – The retrofit of office buildings tends to go unnoticed and unmeasured in the debate about sustainable buildings. The paper provides original thought development and important measurement input which will assist in providing a more accurate and meaningful life cycle assessment of office buildings.

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Quantifying the recurring nature of fitout to assist LCA studies in office buildings

International Journal of Building Pathology and Adaptation ◽

10.1108/ijbpa-04-2017-0020 ◽

2017 ◽

Vol 35 (3) ◽

pp. 233-246 ◽

Cited By ~ 1

Author(s):

Perry Forsythe

Keyword(s):

Life Cycle Assessment ◽

Research Method ◽

Design Methodology ◽

Weighted Average ◽

Central Business District ◽

Embodied Energy ◽

Office Buildings ◽

Evidence Based ◽

Content Type ◽

Business District

Purpose The purpose of this paper is to quantify fitout churn in office buildings to more accurately evaluate the recurrent embodied energy in life cycle assessment studies. Design/methodology/approach Three research methods were used in the context of Central Business District (CBD) office buildings in Sydney. Method 1 involved leasing records from 528 office buildings; method 2, a leasing history from a selective sample of three prime grade office buildings; method 3, a targeted survey of 21 property professionals concerning fitout churn cycle estimates. Findings Prime buildings are the area of most interest to fitout churn because they represent a large proportion of total office floor area. The churn rate differs according to office tenancy type (as defined by small, medium and large leased areas). Large tenants occupy the majority of floor space. Lease duration as obtained from Method 1, offers a reasonable proxy for predicting fitout churn. Using this method coupled with weighted-average calculations, the data indicate a fitout churn rate of 8.2 years. Research limitations/implications Variability concerning the situational context of Sydney CBD office buildings restricts broad generalisability of the findings. However, the research method used in this study would enable broad-based comparison and the potential for verification. Originality/value The main contribution of the research is to improve the ability to accurately predict fitout churn cycles as previous work only involves limited case studies and arbitrary estimates, thus lacking a strong evidence based.

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Application of life cycle assessment and Monte Carlo simulation for enabling sustainable product design

Journal of Engineering Design and Technology ◽

10.1108/jedt-06-2010-0045 ◽

2014 ◽

Vol 12 (3) ◽

pp. 307-315 ◽

Cited By ~ 4

Author(s):

Sekar Vinodh ◽

Gopinath Rathod

Keyword(s):

Monte Carlo Simulation ◽

Monte Carlo ◽

Life Cycle Assessment ◽

Life Cycle ◽

Product Design ◽

Sustainable Product Design ◽

Content Type ◽

Sustainable Product ◽

Manufacturing Organization

Purpose – The purpose of this paper is to present an integrated technical and economic model to evaluate the reusability of products or components. Design/methodology/approach – Life cycle assessment (LCA) methodology is applied to obtain the product’s environmental performance. Monte Carlo simulation is utilized for enabling sustainable product design. Findings – The results show that the model is capable of assessing the potential reusability of used products, while the usage of simulation significantly increases the effectiveness of the model in addressing uncertainties. Research limitations/implications – The case study has been conducted in a single manufacturing organization. The implications derived from the study are found to be practical and useful to the organization. Practical implications – The paper reports a case study carried out for an Indian rotary switches manufacturing organization. Hence, the model is practically feasible. Originality/value – The article presents a study that investigates LCA and simulation as enablers of sustainable product design. Hence, the contributions of this article are original and valuable.

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The importance of embodied energy in carbon footprint assessment

Structural Survey ◽

10.1108/ss-01-2013-0012 ◽

2014 ◽

Vol 32 (1) ◽

pp. 49-60 ◽

Cited By ~ 31

Author(s):

Zaid Alwan ◽

Paul Jones

Keyword(s):

Life Cycle ◽

Carbon Footprint ◽

Embodied Energy ◽

Total Carbon ◽

Design Team ◽

Content Type ◽

Operational Energy ◽

The Impact ◽

Whole Life Cycle

Purpose – The construction industry has focused on operational and embodied energy of buildings as a way of becoming more sustainable, however, with more emphasis on the former. The purpose of this paper is to highlight the impact that embodied energy of construction materials can have on the decision making when designing buildings, and ultimately on the environment. This is an important aspect that has often been overlooked when calculating a building's carbon footprint; and its inclusion this approach presents a more holistic life cycle assessment. Design/methodology/approach – A building project was chosen that is currently being designed; the design team for the project have been tasked by the client to make the facility exemplary in terms of its sustainability. This building has a limited construction palette; therefore the embodied energy component can be accurately calculated. The authors of this paper are also part of the design team for the building so they have full access to Building Information Modelling (BIM) models and production information. An inventory of materials was obtained for the building and embodied energy coefficients applied to assess the key building components. The total operational energy was identified using benchmarking to produce a carbon footprint for the facility. Findings – The results indicate that while operational energy is more significant over the long term, the embodied energy of key materials should not be ignored, and is likely to be a bigger proportion of the total carbon in a low carbon building. The components with high embodied energy have also been identified. The design team have responded to this by altering the design to significantly reduce the embodied energy within these key components – and thus make the building far more sustainable in this regard. Research limitations/implications – It may be is a challenge to create components inventories for whole buildings or for refurbishments. However, a potential future approach for is application may be to use a BIM model to simplify this process by imbedding embodied energy inventories within the software, as part of the BIM menus. Originality/value – This case study identifies the importance of considering carbon use during the whole-life cycle of buildings, as well as highlighting the use of carbon offsetting. The paper presents an original approach to the research by using a “live” building as a case study with a focus on the embodied energy of each component of the scheme. The operational energy is also being calculated, the combined data are currently informing the design approach for the building. As part of the analysis, the building was modelled in BIM software.

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Analyzing the environmental sustainability of primary schools’ facades within the scope of life cycle assessment in Turkey and recommendations for improvement

Smart and Sustainable Built Environment ◽

10.1108/sasbe-04-2021-0072 ◽

2021 ◽

Vol ahead-of-print (ahead-of-print) ◽

Author(s):

Cagla Keles ◽

Fatih Yazicioglu

Keyword(s):

Sustainable Development ◽

Life Cycle Assessment ◽

Life Cycle ◽

Environmental Impact ◽

Environmental Sustainability ◽

Primary Schools ◽

Carbon Emission ◽

Embodied Energy ◽

Public Buildings ◽

Content Type

PurposeThe purpose of this paper is to identify the sustainability conditions of primary schools in Turkey within the scope of the life cycle assessment (LCA). It is aimed to develop optimum alternatives to reduce the environmental impact of primary schools and reach environmental sustainability targets of the sustainable development goals in Turkey.Design/methodology/approachFrom the construction project of 103 buildings located in Istanbul, 10 case buildings with various typical plans were chosen for analysis. The results regarding their life cycle energy and carbon emission for material production, operation and maintenance stages were calculated for a lifespan of 50 years. Results were evaluated and compared within the scope of environmental sustainability. Optimum alternatives for improving the environmental sustainability and performances of selected case buildings’ facades were developed, and the life cycle energy and carbon emission for proposed conditions were calculated. The obtained results were evaluated for current and proposed conditions.FindingsResults showed that reinforced concrete material contributes the most to the life cycle-embodied energy and CO2 emission of buildings. Cooling load increases the life cycle operational energy (LCOE) and CO2 emission of buildings. Using high-performance glazing significantly reduces LCOE and CO2 emission. Recycled and fiber-based materials have significant potential for reducing life cycle-embodied energy and CO2 emission.Originality/valueThis study has been developed in response to achieving sustainable development targets on public buildings in Turkey. In this regard, external walls of primary schools were analyzed within the scope of LCA and recommendations were made to contribute to the policies and regulations requested by the Government of Turkey. This study proves that alternative and novel materials have great potential for achieving sustainable public buildings. The study answers to questions about reducing the environmental impact of primary school buildings by using LCA approach with a holistic point of view.

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An empirical study on life cycle assessment of double-glazed aluminium-clad timber windows

International Journal of Building Pathology and Adaptation ◽

10.1108/ijbpa-01-2019-0001 ◽

2019 ◽

Vol 37 (5) ◽

pp. 547-564 ◽

Cited By ~ 1

Author(s):

Asif M.

Keyword(s):

Life Cycle Assessment ◽

Life Cycle ◽

Construction Industry ◽

Environmental Performance ◽

Energy Efficient ◽

Design Methodology ◽

Powder Coating ◽

Research Community ◽

Embodied Energy ◽

Content Type

Purpose Life cycle assessment (LCA) is a useful tool to determine the environmental performance of materials and products. The purpose of this paper is to undertake the LCA of double-glazed aluminium-clad timber windows in order to determine their environmental performance. Design/methodology/approach The scope of the LCA study covers the production and the use of windows over a 30-year life span. The LCA exercise has been carried out by auditing the materials and processes involved in the making of the windows. Windows production facilities were visited to investigate the respective quantities and embodied energy of the major constituting materials, i.e. timber, aluminium, glass, infill gases and auxiliary components. The main processes involved, i.e. powder coating of aluminium cladding profiles, glazing unit production and window assembly, were also examined. SimaPro software was used to calculate the environmental impacts associated with the windows for three types of glazing infills: Argon (Ar), Krypton (Kr) and Xenon (Xe). Findings Embodied energy of a standard sized (1.2 m×1.2 m) double-glazed aluminium-clad timber window is found to be 899, 1,402 and 5,400 MJ for Argon (Ar), Krypton (Kr) and Xenon (Xe) infill gases, respectively. It is also found that an Argon-filled window can lose 95,130 kWh of energy resulting into over 37,000 kg of CO2 emissions. Originality/value Besides carrying value for research community, the findings of this study can help the building and construction industry adopt windows that are energy-efficient and environmentally less burdensome. It can also help the concerned legislative bodied.

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Life cycle assessment of earthen materials for low-cost housing a comparison between rammed earth and fired clay bricks

International Journal of Building Pathology and Adaptation ◽

10.1108/ijbpa-02-2021-0021 ◽

2021 ◽

Vol ahead-of-print (ahead-of-print) ◽

Author(s):

Hamed Nouri ◽

Majid Safehian ◽

Seyed Majdeddin Mir Mohammad Hosseini

Keyword(s):

Life Cycle Assessment ◽

Life Cycle ◽

Building Materials ◽

Low Cost ◽

Construction Materials ◽

Embodied Energy ◽

Rammed Earth ◽

Energy Calculation ◽

Content Type ◽

Clay Bricks

PurposeAlthough the use of diverse types of bricks as the primary construction materials has been considered for many years, vernacular earthen materials are also widely used for construction with low potential environmental impacts in developing countries. In this study, the life cycle of two types of building materials for wall building is investigated.Design/methodology/approachFor this purpose, life cycle carbon emissions (LCCO2) are compared and embodied energy calculation for rammed earth and fired clay bricks as two construction materials. The complete construction chain using rammed earth, as a modern norm, and fired clay bricks, as the most common construction materials in buildings, is investigated in this research.FindingsStudies on the constructions in Kashan city in the north of Isfahan province, Iran, as a case study, showed that replacing the fired bricks with rammed earth would reduce the CO2 emissions up to 1,245 kg/ton and 4,646 MJ/ton (i.e. more than 95%) of the embodied energy. It also shows that the choice of building materials should be important for building practitioners to consider the environmental impact.Originality/valueThis paper provide life cycle assessment of building materials. The findings of this study help builders and owner to choose sustainable building materials.

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A Comprehensive Framework for Standardising System Boundary Definition in Life Cycle Energy Assessments

Buildings ◽

10.3390/buildings11060230 ◽

2021 ◽

Vol 11 (6) ◽

pp. 230

Author(s):

Hossein Omrany ◽

Veronica Soebarto ◽

Jian Zuo ◽

Ruidong Chang

Keyword(s):

Life Cycle ◽

Energy Use ◽

Embodied Energy ◽

Building Energy Efficiency ◽

System Boundary ◽

Policy Makers ◽

Energy Assessment ◽

Boundary Definition ◽

Comprehensive Framework

This paper aims to propose a comprehensive framework for a clear description of system boundary conditions in life cycle energy assessment (LCEA) analysis in order to promote the incorporation of embodied energy impacts into building energy-efficiency regulations (BEERs). The proposed framework was developed based on an extensive review of 66 studies representing 243 case studies in over 15 countries. The framework consists of six distinctive dimensions, i.e., temporal, physical, methodological, hypothetical, spatial, and functional. These dimensions encapsulate 15 components collectively. The proposed framework possesses two key characteristics; first, its application facilitates defining the conditions of a system boundary within a transparent context. This consequently leads to increasing reliability of obtained LCEA results for decision-making purposes since any particular conditions (e.g., truncation or assumption) considered in establishing the boundaries of a system under study can be revealed. Second, the use of a framework can also provide a meaningful basis for cross comparing cases within a global context. This characteristic can further result in identifying best practices for the design of buildings with low life cycle energy use performance. Furthermore, this paper applies the proposed framework to analyse the LCEA performance of a case study in Adelaide, Australia. Thereafter, the framework is utilised to cross compare the achieved LCEA results with a case study retrieved from literature in order to demonstrate the framework’s capacity for cross comparison. The results indicate the capability of the framework for maintaining transparency in establishing a system boundary in an LCEA analysis, as well as a standardised basis for cross comparing cases. This study also offers recommendations for policy makers in the building sector to incorporate embodied energy into BEERs.

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