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Ahmad, S, Soetanto, R and Goodier, C (2019) Lean approach in precast concrete component production. Built Environment Project and Asset Management, 9(03), 457–70.
Aliakbarlou, S, Wilkinson, S and Costello, S B (2017) Exploring construction client values and qualities: Are these two distinct concepts in construction studies?. Built Environment Project and Asset Management, 7(03), 234-52.
Almén, L and Larsson, T J (2014) Health and safety coordinators in building projects. Built Environment Project and Asset Management, 4(03), 251-63.
Almusharraf, A and Whyte, A (2016) Task-based defect management: Anatomical classification. Built Environment Project and Asset Management, 6(03), 345-58.
Alwan, Z and Gledson, B J (2015) Towards green building performance evaluation using asset information modelling. Built Environment Project and Asset Management, 5(03), 290-303.
Atkins, R and Emmanuel, R (2014) Could refurbishment of “traditional” buildings reduce carbon emissions?. Built Environment Project and Asset Management, 4(03), 221-37.
Awuzie, B and McDermott, P (2016) A systems approach to assessing organisational viability in project-based organisations. Built Environment Project and Asset Management, 6(03), 268-83.
Böhme, T, Escribano, A, Heffernan, E E and Beazley, S (2018) Causes and mitigation for declining productivity in the Australian mid-rise residential construction sector. Built Environment Project and Asset Management, 8(03), 253–66.
Bosch, A, Volker, L and Koutamanis, A (2015) BIM in the operations stage: Bottlenecks and implications for owners. Built Environment Project and Asset Management, 5(03), 331-43.
De Silva, N, Weerasinghe, R P N P, Madhusanka, H W N and Kumaraswamy, M (2017) Relationally integrated value networks for total facilities management. Built Environment Project and Asset Management, 7(03), 313-29.
Fahmy, A, Hassan, T, Bassioni, H and McCaffer, R (2019) Dynamic scheduling model for the construction industry. Built Environment Project and Asset Management, 10(03), 313–30.
Geekiyanage, D and Ramachandra, T (2020) Nexus between running costs and building characteristics of commercial buildings: hedonic regression modelling. Built Environment Project and Asset Management, 10(03), 389–406.
Hamzeh, F, Rached, F, Hraoui, Y, Karam, A J, Malaeb, Z, El Asmar, M and Abbas, Y (2019) Integrated project delivery as an enabler for collaboration: a Middle East perspective. Built Environment Project and Asset Management, 9(03), 334–47.
Hasan, A, Elmualim, A, Rameezdeen, R, Baroudi, B and Marshall, A (2018) An exploratory study on the impact of mobile ICT on productivity in construction projects. Built Environment Project and Asset Management, 8(03), 320–32.
Holt, G D and Edwards, D J (2014) Machinery transportation management: case study of “plant-trailer” H&S incidents. Built Environment Project and Asset Management, 4(03), 264-80.
Ismail, S and Haris, F A (2014) Constraints in implementing Public Private Partnership (PPP) in Malaysia. Built Environment Project and Asset Management, 4(03), 238-50.
Javed, A A, Pan, W, Chen, L and Zhan, W (2018) A systemic exploration of drivers for and constraints on construction productivity enhancement. Built Environment Project and Asset Management, 8(03), 239–52.
Kamara, J M (2017) Maintaining focus on clients’ requirements using the DQI tool: Towards a requirements-oriented project process. Built Environment Project and Asset Management, 7(03), 271-83.
Karunaratne, T L W and De Silva, N (2019) Demand-side energy retrofit potential in existing office buildings. Built Environment Project and Asset Management, 9(03), 426–39.
- Type: Journal Article
- Keywords: Sri Lanka; Energy consumption; Energy management; Office buildings; Energy demand; Energy retrofits;
- ISBN/ISSN: 2044-124X
- URL: https://doi.org/10.1108/BEPAM-10-2017-0103
- Abstract:
Office buildings confront with the issue of high energy demand during the day time mainly due to heavy use of energy for HVAC and lighting systems. Demand-side energy retrofits (DSER) are identified as effective in controlling electricity demand of existing buildings. The purpose of this paper is to analyse the potential of incorporating DSER in to existing office buildings. The paper reports the cost benefits of using DSER in existing office buildings. Furthermore, it reveals several enablers that can be used to promote retrofits in office buildings of Sri Lanka.Design/methodology/approach An industry survey was conducted by selecting a sample of 35 office buildings to study the usage of DSER in office buildings of Sri Lanka. Furthermore, three case studies were conducted to analyse the costs benefits of widely used DSER techniques in office buildings.Findings Research revealed that the use of DSER techniques in existing office buildings of Sri Lanka is at a lower level. However, it found that the financial viability of those DSER was at a promising level. Furthermore, 11 enablers in two levels as organisational level and national level were identified to enhance the use of DSER.Originality/value The study justifies the potential of DSER in reducing energy demand of existing office buildings through in-depth cost benefit analysis, which is useful for a country like Sri Lanka which faces massive energy crisis. This encourages Facility Managers towards using DSER to reduce building energy demand. Furthermore, study provides enablers at organisational and national levels to enhance the use of DSER.
Kassem, M, Kelly, G, Dawood, N, Serginson, M and Lockley, S (2015) BIM in facilities management applications: A case study of a large university complex. Built Environment Project and Asset Management, 5(03), 261-77.
Ke, Y, Ling, F Y, Ning, Y and Zhang, Z (2019) Managing relationships in large public projects: comparative study of China and Singapore. Built Environment Project and Asset Management, 9(03), 348–63.
Kissi, E, Agyekum, K, Baiden, B K, Tannor, R A, Asamoah, G E and Andam, E T (2019) Impact of project monitoring and evaluation practices on construction project success criteria in Ghana. Built Environment Project and Asset Management, 9(03), 364–82.
Kumara, W H C D, Waidyasekara, K G A S and Weerasinghe, R P N P (2016) Building management system for sustainable built environment in Sri Lanka. Built Environment Project and Asset Management, 6(03), 302-16.
Kumaraswamy, M, Mahesh, G, Mahalingam, A, Loganathan, S and Kalidindi, S N (2017) Developing a clients’ charter and construction project KPIs to direct and drive industry improvements. Built Environment Project and Asset Management, 7(03), 253-70.
Lindkvist, C (2015) Contextualizing learning approaches which shape BIM for maintenance. Built Environment Project and Asset Management, 5(03), 318-30.
Ling, F Y Y (2018) International comparison of performance of public projects. Built Environment Project and Asset Management, 8(03), 281–92.
Ling, F Y Y and Khoo, W W (2016) Improving relationships in project teams in Malaysia. Built Environment Project and Asset Management, 6(03), 284-301.
Ling, F Y, Zhang, Z and Wong, W T (2020) How personality traits influence management styles of construction project managers. Built Environment Project and Asset Management, 10(03), 453–68.
Lokuge, W, Gamage, N and Setunge, S (2016) Fault tree analysis method for deterioration of timber bridges using an Australian case study. Built Environment Project and Asset Management, 6(03), 332-44.
Love, P E D, Zhou, J, Matthews, J, Sing, C-P and Carey, B (2015) A systems information model for managing electrical, control, and instrumentation assets. Built Environment Project and Asset Management, 5(03), 278-89.
Mahmood, S, Ahmed, S M, Panthi, K and Kureshi, N I (2014) Determining the cost of poor quality and its impact on productivity and profitability. Built Environment Project and Asset Management, 4(03), 296-311.
Mathar, H, Assaf, S, Hassanain, M A, Abdallah, A and Sayed, A M (2020) Critical success factors for large building construction projects. Built Environment Project and Asset Management, 10(03), 349–67.
Motawa, I and Almarshad, A (2015) Case-based reasoning and BIM systems for asset management. Built Environment Project and Asset Management, 5(03), 233-47.
Mwesigwa, R, Nabwami, R, Mayengo, J and Basulira, G (2020) Contractual completeness as a cornerstone to stakeholder management in public private partnership projects in Uganda. Built Environment Project and Asset Management, 10(03), 469–84.
Ohueri, C C, Enegbuma, W I, Wong, N H, Kuok, K K and Kenley, R (2018) Labour productivity motivation framework for Iskandar Malaysia. Built Environment Project and Asset Management, 8(03), 293–304.
Olanrewaju, A A and Anavhe, P J (2014) Perceived claim sources in the Nigerian construction industry. Built Environment Project and Asset Management, 4(03), 281-95.
Olatunji, O A and Akanmu, A (2015) BIM-FM and consequential loss: How consequential can design models be?. Built Environment Project and Asset Management, 5(03), 304-17.
Oyewole, E O and Dada, J O (2019) Training gaps in the adoption of building information modelling by Nigerian construction professionals. Built Environment Project and Asset Management, 9(03), 399–411.
Pärn, E A and Edwards, D (2017) Vision and advocacy of optoelectronic technology developments in the AECO sector. Built Environment Project and Asset Management, 7(03), 330-48.
Sackey, E, Tuuli, M and Dainty, A (2019) Expansive learning in contemporary construction organisations. Built Environment Project and Asset Management, 9(03), 383–98.
Schultz, A L (2017) Integrating lean and visual management in facilities management using design science and action research. Built Environment Project and Asset Management, 7(03), 300-12.
Shojaei, P and bolvardizadeh, A (2020) Rough MCDM model for green supplier selection in Iran: a case of university construction project. Built Environment Project and Asset Management, 10(03), 437–52.
Shooshtarian, S, Lingard, H and Wong, P S (2020) Using the cost of construction work to trigger legislative duties for WHS: the Australian experience. Built Environment Project and Asset Management, 10(03), 369–87.
Sridarran, P and Fernando, N G (2016) Change management framework to enable sustainable outsourcing of facilities management services. Built Environment Project and Asset Management, 6(03), 317-31.
Tanko, B L, Abdullah, F, Mohamad Ramly, Z and Enegbuma, W I (2018) An implementation framework of value management in the Nigerian construction industry. Built Environment Project and Asset Management, 8(03), 305–19.
Ugulu, R A and Allen, S (2018) Using the learning curve theory in the investigation of on-site craft gangs’ blockwork construction productivity. Built Environment Project and Asset Management, 8(03), 267–80.
Vilventhan, A and Rajadurai, R (2019) 4D Bridge Information Modelling for management of bridge projects: a case study from India. Built Environment Project and Asset Management, 10(03), 423–35.
Weerasinghe, R P N P and Sandanayake, Y G (2017) Collaborative facilities management model: Sri Lankan perspective. Built Environment Project and Asset Management, 7(03), 284-99.
Whyte, A and Donaldson, J (2015) Digital model data distribution in civil engineering contracts. Built Environment Project and Asset Management, 5(03), 248-60.
Wuni, I Y and Shen, G Q (2020) Stakeholder management in prefabricated prefinished volumetric construction projects: benchmarking the key result areas. Built Environment Project and Asset Management, 10(03), 407–21.
Xia, B, Wu, T, Skitmore, M, Chen, Q, Li, M and Zuo, J (2016) Delivering sustainable communities: A case study in China. Built Environment Project and Asset Management, 6(03), 253-67.
Yap, J B H and Chow, I N (2020) Investigating the managerial ‘‘nuts and bolts’’ for the construction industry. Built Environment Project and Asset Management, 10(03), 331–48.
Zahed, S E, Shahooei, S, Farooghi, F, Shahandashti, M and Ardekani, S (2019) Life-cycle cost analysis of a short-haul underground freight transportation system for the DFW Airport. Built Environment Project and Asset Management, 9(03), 440–56.
Zarghami, S A, Gunawan, I and Schultmann, F (2019) Entropy of centrality values for topological vulnerability analysis of water distribution networks. Built Environment Project and Asset Management, 9(03), 412–25.