Next Article in Journal
Life Cycle Cost Analysis of a Single-Family House in Sweden
Next Article in Special Issue
An Overview about the Current Situation on C&D Waste Management in Italy: Achievements and Challenges
Previous Article in Journal
Economic Evaluation of the Indoor Environmental Quality of Buildings: The Noise Pollution Effects on Housing Prices in the City of Bari (Italy)
Previous Article in Special Issue
Dynamic Properties of Granulated Rubber Using Different Laboratory Tests
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Strategies for Effective Waste Reduction and Management of Building Construction Projects in Highly Urbanized Cities—A Case Study of Hong Kong

Department of Building and Real Estate, The Hong Kong Polytechnic University, Hung Hom, Hong Kong
*
Author to whom correspondence should be addressed.
Submission received: 9 April 2021 / Revised: 10 May 2021 / Accepted: 12 May 2021 / Published: 19 May 2021
(This article belongs to the Collection Utilization of Waste Materials in Building Engineering)

Abstract

:
Hong Kong is a densely populated city with high-rise developments, and as in other metropolitan cities, the amount of waste generated from construction projects in the city is increasing annually. The capacity of existing landfills is expected to be saturated by the 2020s. Construction waste management has been implemented for years but the performance is still not satisfactory. The aim of this research paper is to explore and formulate strategies and measures for effective construction waste management and reduction in highly urbanized cities such as Hong Kong. A desktop study on construction waste management practices was carried out for a preliminary understanding of the current situation in Hong Kong. Semistructured interviews and focus group meetings were further conducted to shed light on how to improve construction waste reduction and management in Hong Kong. The main contributions of this research study are the potential short-term, medium-term, and long-term strategies, which are related to the design stage, tender stage, construction stage, and government support. The five major strategies recommended are financial benefits to stakeholders, public policies in facilitating waste sorting, government supports for the green building industry, development of a mature recycling market, and education and research in construction waste minimization and management.

1. Introduction

Construction activities produce large quantities of solid waste daily from construction and demolition, which cause an adverse impact on our environment [1,2]. The collection, treatment, and disposal of solid waste, particularly in highly urbanized cities become a difficult problem to solve [3]. Both developed and developing countries such as the United States (US) and China are running short of landfill sites and facing a challenging problem of environmental degradation caused by construction waste seeking landfill sites for construction waste [2,4]. Hong Kong is one of the world’s leading business centers. The population is more than 7.52 million living in about 1107 square kilometers with a high population density of 6793 people per square kilometer [5].
Construction waste of Hong Kong is mainly composed of a mixture of solid inert and noninert waste generated from excavation, site work, demolition, renovation and, civil and building projects [6,7]. Inert waste, which is composed mainly of paper, sand, wood, bricks, and concrete, are disposed of at three strategic municipal solid waste landfills and used as land reclamation materials [7,8,9]. Hong Kong cannot rely solely on reclamation to dispose of our inert construction waste for sustainable development [10]. From the Environmental Protection Department report [11], generation of construction waste in 2019 had only decreased by 3.3% from 2018 amounting to 1.44 million tonnes and the reuse rate of inert materials had slightly increased by 2% to 92%. Although parts of the inert waste particularly concrete aggregates have high reuse potential [4,12], the mixing of inert and noninert waste generated from construction works increases the difficulty of separation ending up in a large portion of inert waste at public filling areas and landfills [7]. Reuse of demolished concrete to substitute natural aggregates can solve the shortage problem of natural aggregates [13] and preserve valuable space in landfills [14]. “Preservation of the environment and conservation of the rapidly diminishing natural resources should be the essence of sustainable development” [12] (p. 72). Reviewing the practices of waste management indicated that the current strategies for waste reduction and management of building construction projects in a highly urbanized city of Hong Kong are not effective [15]. Hong Kong should develop and implement effective strategies to reduce and manage construction waste and handle the problem in a more environmentally responsible way [8].
The Hong Kong Polytechnic University had carried out a consultancy research project for the Construction Industry Council (CIC) exploring effective strategies for management and reduction of construction and demolition waste in Hong Kong and summarized in eight reports and a summary report. The aim of this paper is to develop and summarize short-term, medium-term, and long-term strategies to improve the effectiveness of waste management for building construction projects in highly urbanized cities such as Hong Kong. The novelty of this research paper is the categorization of the strategies according to the timeline of the building projects. This paper serves as a comprehensive collection of all the updated strategies for the government officials’ and professional practitioners’ reference to improve C&D minimization and management.

2. Literature Review: Current Practices of Construction Waste Management in Hong Kong

The construction industry had disposed of an average of about 4000 tonnes (25% of total disposal) of C&D waste at landfills per day in 2019. Most of the mixed construction is disposed of at sorting facilities or landfills without sorting. Our landfills and public fill capacity will be saturated by the 2020s according to the current trend of construction waste management [16]. The government is examining ways to reduce construction waste.
There are various strategies, approaches, and measures of construction waste management practicing in the public and private sectors. Poon and Poon et al. have identified seven effective good practices (see Section 2.1, Section 2.2, Section 2.3, Section 2.4, Section 2.5, Section 2.6 and Section 2.7) [8,17,18,19], which are recommended to be included in the strategies for construction waste management in highly urbanized cities. Other approaches such as circular economy, zero waste approach, and green rating system are also discussed in Section 2.8, Section 2.9 and Section 2.10.

2.1. Construction Waste Disposal Charging Scheme (CWDCS)ConstructionC

Since the implementation of CWDCS in 2005, the total waste generation had significantly reduced but the effectiveness started to decrease after three years [20,21,22,23]. The charging standard was increased in 2017 in order to improve the effectiveness of CWDCS, as illustrated in Table 1. Reducing disposal costs can create a significant incentive for the construction industry in reducing construction waste.

2.2. Site Waste Management Plans

Site waste management plan (SWMP) is becoming popular nowadays as a valuable approach for the purpose of assisting construction stakeholders to anticipate the type of C&D waste as well as estimate the quantity for making the right decisions in order to manage it [24]. A waste management plan is required for all public projects and has proved that reuse and recycling can be improved [9]. However, the effectiveness of SWMP is limited by site constraints and overhead costs [25]. The majority of sites do not have enough areas to carry out on-site sorting, which is labor intensive. The enforcement of SWMP is not common in private projects. It is necessary to provide more sorting facilities and explore the means to reduce overhead costs.

2.3. Proper Design

Appropriate design can avoid waste generation at the very beginning stage of construction works [18,26], which includes dimensional coordination and standardization, minimizing the use of temporary works, design for use of recycled materials, avoiding late design modifications, applying low-waste building technologies, backfilling cut and fill by the excavated soils, modeling design information, etc. Zhang et al. and Baldwin et al. suggested that modeling design information flows could evaluate optimized design solutions [27,28]. However, lacking mandatory requirements in the green building assessment tool, designing out waste is not widely practicing in the construction industry [19]. Future research on how to properly designing out waste is necessary.

2.4. Deconstruction

Deconstruction, which is also called selective demolition, can effectively facilitate the reuse and recycling of construction waste [25,29]. Deconstruction is carried out reversing the construction processes requiring planned sorting of the demolished materials according to their categories so as to prevent contaminating the recyclable materials such as wood, paper, cardboard, plastic, metal, and concrete aggregates [29,30].
Expensive manual sorting and insufficient recycling outlets are deterring contractors from carrying out deconstruction. Concurrently the recycling market in Hong Kong is underdeveloped. A mature recycling market is essential to provide more outlets for recyclable items.

2.5. Prefabrication and Modular Construction

Prefabrication can reduce about 52% of construction waste by minimizing on-site wet trade and improving buildability and perform better than conventional construction methods in environmental, economic, and social aspects [15,19,31,32,33,34]. The Hong Kong Housing Authority has been a pioneer in using prefabrication in building housing estates. However, the implementation of prefabrication is not common in the private sector, and there is room for improvement. Furthermore, prefabrication has some disadvantages including less flexibility with plans and manufacturing, and limitation on transportation [35].

2.6. On-Site and Off-Site Waste Sorting

On-site sorting is effective in reducing construction waste and recover valuable materials for reuse and recycling thus reducing disposal costs [35]. However, contractors are reluctant to carry out on-site sorting in spite of high tipping costs due to congested site conditions, tight construction period, high labor demand, expensive operation costs, and lack of recycling outlets [7]. Off-site sorting can be an alternative to promote reuse and recycling since the operating costs can be less expensive than direct disposal at landfills [2]. It is necessary to develop more customized on-site recycling equipment and thriving off-site recycling [36]. How to select a proper location for off-site construction waste sorting facilities that can reduce transportation costs and prevent noise and dust is an important factor to be considered.

2.7. Reduce, Reuse and Recycling

Most of the C&D waste research is largely focused on the “three Rs” principle of waste (reduction, reuse, and recycling), also known as the waste hierarchy [24,37]. EPD has pointed out in a 2005 report that “the burden of Hong Kong’s landfills can be reduced through reuse, recovery and recycling” [38] (chapter 1, point 9). Research on reusing waste glass as an aggregate in concrete or additive in cement pastes or mortar have been conducted [39,40,41]. Though recycling technologies have been developed in recent years, how to promote the use of recycled products is still an issue to be solved. In addition, changing an individual’s recycling attitude and behavior is of utmost importance in achieving sustainable C&D waste reduction and management [42].

2.8. Circular Construction

Circular construction is based on the concept of a circular economy model, which tries to keep the products and materials “in flow” by means of effective reuse strategies, thus reducing the use of virgin materials and negative environmental impacts [43,44]. This can be accomplished using smart design and circular value chains, which is crucial for a sector to reduce both its waste and the amount of virgin resources used [45]. Transition to a circular construction involves changes in value chains, from building design, from new professional behavior to new ways of turning waste into a resource. It is necessary to promote C&D waste management guidelines in order to “contribute to resource efficiency and enable the transition from a Linear to a Circular Economy” [46] (p. 2).

2.9. Zero Waste Approach

Authorities need to look for alternative waste management systems due to the lack of landfill sites in urban areas. Zero waste (ZW), which is a perceptive system of waste management, has been introduced as an alternative solution for waste problems in recent decades in many cities such as San Francisco, Vancouver, and Adelaide [47]. ZW concept motivates sustainable consumption and production, optimization of resource recovery and recycling, and prevents wastes from incineration and landfilling [24]. Research conducted by Zaman and Lehmann proposed that a ZW city should recover 100% of its resources from waste and should reach a 100% recycling rate, although this is an ideal case [48].

2.10. Green Rating System

Green rating systems throughout the world are widely applied in order to assess the sustainability of construction processes. In Hong Kong, these sustainability assessment tools including Building Environmental Assessment Method Plus (BEAM Plus) and Leadership in Energy and Environmental Design (LEED). For instance, BEAM Plus New Buildings came to action in 2012; BEAM Plus Interiors (Commercial, Retail, and Institutional) was introduced in 2013; and BEAM Plus Existing Buildings (Comprehensive and Selective Scheme) was launched in 2016. The materials aspects in these standards and assessments address the issues of design approaches, selection and use of materials, as well as C&D waste reduction.

2.11. Research Gap

Although there are many studies on the reduction and management of C&D waste, little attention has been paid to a comprehensive and holistic attempt to summarize all the updated strategies and measures in Hong Kong. The contributions of this work have been the classification of these strategies and measures in short, medium, and long terms, and the timelines of these strategies to be adopted under design, tender, and construction stages. These findings formulate a good reference for the government since it needs to support the construction industry in C&D waste reduction and management.

3. Research Methods

In this paper, a combination of literature review, personal interviews, and focus group meetings was used for achieving the research aim. After completion of the research design and pilot study, construction practitioners were interviewed in the second stage to collect their expertise comments on construction waste reduction and management. The interview questions were formulated based on the literature review. In the third stage, the summary of the interviews was presented at two focus group meetings, followed by discussing the interview findings and encouraging the participants to propose strategies on effective waste reduction and management of building construction projects in highly urbanized cities.

3.1. Desktop Study

A desktop study on scholarly papers, government websites, and the nine reports produced by the Hong Kong Polytechnic University from the consultancy project [5] formed the reference materials for this research. The desktop study was carried out covering the literature from 2000 to 2020. The type of database/e-resource used included Web of Science, Scopus, Science Direct, and Google Scholar. A list of terms for searching included construction and demolition waste, waste management, construction waste, demolition waste, etc. Successful overseas and local examples of construction waste management policies and measures were identified for analysis. An evaluation of Hong Kong’s current construction waste management was also conducted to provide background information for this research. Current good practices and limitations of construction waste management were identified and summarized in Section 2. The literature review took two months to be completed and summarized for formulating the issues to be discussed during interviews and focus group meetings.

3.2. Personal Interviews

The interviews were carried out in the participants’ offices in 2016. A set of interview questions was formulated from the findings of the literature review. The interview guide is attached to Appendix A. The research team has visited 20 construction industry practitioners including two developers, four architects, one building surveyor, three main contractors, one demolition contractor, and six representatives from Architectural Services Department, Civil Engineering and Development Department, Development Bureau, Environmental Protection Department, and Housing Department in 12 interviews. The sample size is usually small in qualitative research, which is within 15 to 20 when the point of diminishing return occurs [49,50,51,52]. The aim of the interview was to collect professional views and comments on the current construction waste management practices and propose improvement. The questions focused on the implementation of waste management in public and private sectors, the incurred barriers and difficulties in implementing, strategies and measures for improvement, recommendations to the government, and the effectiveness of enforcing BEAM Plus to facilitate waste management. Interviewees were invited to share their success stories in construction waste management. They were also invited to define the roles of client, designer, and contractor in construction waste management. The main concern of clients/developers is the amount of revenue return. Designers shared their valuable experiences on construction waste management, while contractors voiced out their encountered difficulties during implementation. Government officials shed light on the principles of construction waste management legislation. The duration of the interviews ranged from half an hour to one hour. The interviews were recorded with a mobile phone and subsequently translated into English for the written transcript.

3.3. Focus Group Meetings

The findings from the literature review and interviews were discussed in two focus group meetings. The focus group participants included architect, surveyor, main contractor, SME contractor, Housing Department, Environmental Protection Department, Civil Engineering and Drainage Department, and Hong Kong Green Building Council. There were eight participants in each of the focus groups. The meetings were begun with the presentation of findings by the authors. The participants then shared their insight into construction minimization and management strategies.
The conversations in the meetings were recorded with a recording pen and subsequently translated into English for the written transcript. The summary of findings and suggestions from the two focus groups on reducing C&D waste and improving construction waste management are discussed in Section 4.1 and Section 4.2.

4. Research Findings from Interviews and Focus Group Meetings

4.1. Barriers and Difficulties in Construction Waste Management

The main barriers and difficulties in construction waste management are low incentive of clients due to high initial cost, congested site for carrying out on-site sorting, high recycling cost, worry about the quality of recycled products, immature recycling market, insufficient skilled recycling labor, the low penalty of illegal dumping compared to the cost of recycling, inadequate government support, and low accreditations for recycling in BEAM Plus, which are tabulated in Table 2.

4.2. Suggestions

According to the findings from the literature review, interviews, and focus group meetings, suggestions to improve construction waste management were categorized into four main aspects: design stage, tender stage, construction stage, and government support, which are summarized in Table 3. These suggestions formed the guidelines for exploring strategies for effective construction waste management in an urbanized city.

5. Proposed Strategies for Promoting Construction Waste Reduction and Management in Hong Kong

Planning and policies can be divided into short, medium, and long terms. Gartenstein has clearly elaborated the functions of short-, medium-, and long-term planning [53]. Short-term objectives are geared towards short-term needs and should serve the long-term goals. Medium-term planning brings together the clarity of shorter-term goals with the depth of longer-term planning. Long-term plans are concrete means to express a larger vision and adjusted over time as the medium-term situation unfolds. Proposed strategies promoting construction waste management in Hong Kong can also be classified as short (S), medium (M), and long (L) terms. Short-term strategies relate to readily available means. Medium-term strategies enhance the development of existing good practices in construction waste management. Long-term strategies are mostly associated with public policies, research, and education. Success in implementing construction waste reduction and management requires the participation and cooperation of clients, designers, contractors, government, and the general public. The following sections discuss the proposed strategies for construction stakeholders and government according to design stage, tender stage, construction stage, and government support.

5.1. Proposed Strategies for Construction Stakeholders

The proposed strategies for effective construction waste reduction and management concern clients, building designers, contractors, and the government relating to the five main strategies in the design stage, tender stage, construction stage, and government support, which cover financial benefits to stakeholders, public policies in facilitating waste sorting, government supports for the green building industry, development of a mature recycling market, and education and research in construction waste management.

5.1.1. Design Stage

According to the hierarchy model proposed by Peng et al. [4], the most effective mean of construction waste reduction is to reduce at the source. SWMP should be included in the early design stage, considering the application of no-frills and fuss-free design and using low-waste building technologies. Low-waste building technologies include precast/prefabrication, standard/modular and adaptive design, reuse of existing building foundations and structures, reusable temporary works, sustainable/recyclable building materials, drywall systems, etc. Setting up an “integrated project design” including multiple disciplines at the design stage can minimize abortive works. “Design and build” contract can enable contractors to formulate SWMP tailor-made for their company management and site conditions. Building Information Modeling (BIM) can help to review the crashes in virtual construction sequences, which can avoid abortive work.

5.1.2. Tender Stage

Implementation of SWMP can be specified in the tender stage. Introducing contractual “recycling rates” and “award and penalty” schemes in tender documents can create incentives for reducing construction waste. The tender can offer a certain percentage of the contract sum as a bonus for contractors who can achieve the waste reduction target in the SWMP. Contractors will be awarded for meeting the target and penalized for noncompliance. Usually, different construction trades are working simultaneously in a congested site making it difficult to carry out on-site sorting. Clients can allow a slightly longer construction period for on-site sorting. A longer construction period can also optimize the reuse of temporary work. Off-site sorting can be included when there is not sufficient storage space. Contractors should be encouraged to set up a communication platform for coordinating the reuse and recycling of construction waste among the industry.

5.1.3. Construction Stage

Table 4 categorized the suggested measures of improving construction waste management for different stakeholders according to design, tender, and construction stage in short-, medium-, and long-term implementation timeframe, which can serve as guidelines in formulating short-term, medium-term, and long-term construction waste management strategies.

5.2. Recommendations to the Government

Cost effectiveness is a significant factor that influences the stakeholders’ waste management behavior and the government plays a significant role in promoting construction waste management [54]. In the focus group meetings, contractors argued that construction waste management was not a priority issue since most clients were not interested in reducing waste. Clients explained that they were not interested because the requirements for accrediting 30% and 60% of recycling construction waste in BEAM Plus were too stringent and contributing to only 1 credit and 2 credits, respectively [19]. Moreover, the requirements of reuse and recycling construction waste in demolition projects were not stated comprehensively and impractical. Beam Plus provides a significant financial incentive to clients in terms of gross floor area concession in achieving certain accreditations. However, other viable methodologies and passive measures for reducing construction waste are not considered for accreditation in BEAM Plus, such as reducing the use of steel, backfilling, revitalizing and reuse of existing foundation and structural framework, revising method statements to address different site conditions to reduce abortive work [19]. Furthermore, a monitoring system for implementing SWMP is lacking. The Government can advise HKGBC to review the BEAM Plus scoring system.
The recycling industry is poorly developed without adequate government support. Currently, there are only two concrete and one timber recycling companies. The capacity of recycling contractors could not cope with the amount of waste produced, which led to high recycling costs. Waste sorting can help to increase recycling rates. However, the high labor and transportation costs of recycling have impeded recycling. It is suggested to facilitate off-site sorting by providing more public waste sorting sites, which is recommended to be located adjacent to landfill in a 1:1 ratio. Government can consider privatizing the management of waste sorting facilities to assist the recycling market in creating momentum for development. In addition, the penalty for illegal dumping is insignificant, compared to the cost of minimizing construction waste. Some interviewees suggested a drastic increase in waste disposal charges, e.g., HK$ 500/ton could significantly reduce construction waste or provide incentives to perform off-site sorting. Government can streamline the application for recycling subsidies and let out more short-term tenancy land to promote the development of local recycling industries. The recycling cost will be reduced when more recycling outlets are available. Therefore, policy to provide financial incentives for the setting up of local recycling industries should be explored.
The government also has an obligation to promote green technologies. The government should be more proactive in approving innovative green technologies. The Building Department (BD) can work with the CIC to conduct training classes for workers using the new technologies. The Building Department can consider reclassifying the extensive reuse of existing buildings under “New Buildings” instead of “Alteration and Addition Works” to facilitate flexibility in design.
Other major sources of construction waste include packaging materials and timber. Recyclable plastic packages and timber waste offer economic value to recycling contractors. Mandatory selective sorting of plastic and timber waste can initiate contractors into solving the waste sorting problem arising from site constraints. Since 50% of construction waste is unrecyclable contaminated timber formwork, it can be incinerated and turned to electrical energy to operate the incinerators or other local industries.
The suggestions for the government to promote effective construction waste reduction and management are summarized in Table 5.

6. Conclusions

Construction waste management has been implemented for years in Hong Kong, but the performance is still not satisfactory. Government and building professionals are willing to work out effective strategies for construction waste reduction and management. Economic consideration is the dominating factor for success. Successful overseas examples in construction waste management involve legislation, high landfill tax, development of a mature recycling market, efficient platform for waste exchange, and a comprehensive credit-earning building environmental assessment system. Barriers to effective construction waste management and reduction were identified from interviews and focus group meetings, which were related to high overhead cost versus low economic return, inadequate government support, and incomprehensive coverage of waste management measures in the accreditation offered by BEAM Plus. Focus group discussions were conducted to explore potential strategies for effective construction waste reduction and management. Clients, designers, and contractors should cooperate with each other to improve waste management practices. Government facilitation and public support are also crucial factors of success. The proposed strategies were divided into short, medium, and long terms. From the research findings, 4 short-term strategies consisting of 22 measures, 5 medium-term strategies comprising 14 measures, and 5 long-term strategies with 11 measures were developed, which relate to the five main strategies in the design stage, tender stage, construction stage, and government support. The strategies include financial benefits to stakeholders, public policies in facilitating waste sorting, government support for the green building industry, development of a mature recycling market, and education and research in construction waste management.

Author Contributions

Conceptualization, C.-S.P.; methodology, A.T.W.Y.; data curation, A.T.W.Y., Z.W. and I.W.; writing-original draft preparation, I.W.; writing-review and editing, A.T.W.Y., supervision, C.-S.P. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by The Hong Kong Polytechnic University (Project of Strategic Importance and G-YBQD), as well as the Construction Industry Council.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Data Availability Statement

New data were created or analyzed in this study. Data will be shared upon request and consideration of the authors.

Acknowledgments

The work described in this paper was supported by two grants from The Hong Kong Polytechnic University (Project of Strategic Importance) and G-YBQD, as well as the Construction Industry Council. The authors are grateful for all of the respondents participating in the interviews and focus group meetings, without whom, this research would not have been possible.

Conflicts of Interest

The authors declare no conflict of interest.

Abbreviations

BDBuilding Department
BEAM PlusBuilding Environmental Assessment Method Plus
BIMBuilding Information Modeling
CICConstruction Industry Council
CWDCSConstruction Waste Disposal Charging Scheme
EPDEnvironmental Protection Department
HKGBCHong Kong Green Building Council
LEEDLeadership in Energy and Environmental Design
UNEPUnited Nations Environment Program
SWMPSite Waste Management Plans

Appendix A

Interview Guide
  • Please furnish us with successful stories of C&D waste management and reduction in your organization.
  • What are your concerns on C&D waste management and reduction practices in Hong Kong?
  • What are the barriers and difficulties to C&D waste management and reduction practices in Hong Kong?
  • What are the strategies and measures for improving C&D waste management and reduction practices in Hong Kong?
  • What should the HK Government do to take the lead and facilitate the C&D waste reduction and management?
  • What should the clients do to promote C&D waste reduction and management in Hong Kong?
  • What should the designers do to facilitate the C&D waste minimization in the design stage as well as and to supervise the C&D waste management of contractor in the construction stage?
  • What should the contractor do to reduce and management C&D waste prevention, reduction and management on site?
  • What is the concern you have regarding the BEAM Plus requirements on the C&D Waste Management? Whether the requirements are too stringent? Or more promotion/incentive is required?

References

  1. Osmani, M.; Glass, J.; Price, A. Architects’ perspectives on construction waste reduction by design. Waste Manag. 2008, 28, 1147–1158. [Google Scholar] [CrossRef] [PubMed]
  2. Lu, W.; Yuan, H. Off-site sorting of construction waste: What can we learn from Hong Kong? Resour. Conserv. Recycl. 2012, 69, 100–108. [Google Scholar] [CrossRef] [Green Version]
  3. United Nations Environment Program (UNEP). Principles of Solid Waste Management; United Nations Environment Program: Nairobi, Kenya, 2005. [Google Scholar]
  4. Peng, C.-L.; Scorpio, D.E.; Kibert, C.J. Strategies for successful construction and demolition waste recycling operations. Constr. Manag. Econ. 1997, 15, 49–58. [Google Scholar] [CrossRef]
  5. World Population Review. Hong Kong Population 2020. Available online: https://worldpopulationreview.com/countries/hong-kong-population/ (accessed on 9 April 2020).
  6. Environmental Protection Department (EPD). Strategic Landfills. 2017. Available online: http://www.epd.gov.hk/epd/english/environmentinhk/waste/prob_solutions/msw_strategic.html (accessed on 12 April 2018).
  7. Poon, C.S.; Yu, A.T.; Ng, L. On-site sorting of construction and demolition waste in Hong Kong. Resour. Conserv. Recycl. 2001, 32, 157–172. [Google Scholar] [CrossRef]
  8. Poon, C.S.; Yu, A.T.W.; Ng, L.H. A Guide for Managing and Minimizing Building and Demolition Waste; The Hong Kong Polytechnic University: Hung Hom, Kowloon, 2001; ISBN 962-367-311-6. [Google Scholar]
  9. Tam, V.W. On the effectiveness in implementing a waste-management-plan method in construction. Waste Manag. 2008, 28, 1072–1080. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  10. Environmental Protection Department (EPD). Future Landfill Development in Hong Kong: View-Sharing Meeting on 2 March 2002. 2017. Available online: http://www.epd.gov.hk/epd/english/environmentinhk/waste/pub_consult/landfill_backgr_r01.htm (accessed on 11 March 2018).
  11. Environmental Protection Department (EPD). Monitoring of Solid Waste in Hong Kong, Waste Statistics for 2019. Statistic Unit, EPD, Hong Kong. 2020. Available online: https://www.wastereduction.gov.hk/sites/default/files/msw2019.pdf (accessed on 7 May 2020).
  12. Rao, A.; Jha, K.N.; Misra, S. Use of aggregates from recycled construction and demolition waste in concrete. Resour. Conserv. Recycl. 2007, 50, 71–81. [Google Scholar] [CrossRef]
  13. Khalaf, F.M.; Devenny, A.S. Recycling of demolished masonry rubble as coarse aggregate in concrete: Review. J. Mater. Civ. Eng. 2004, 16, 331–340. [Google Scholar] [CrossRef]
  14. Schlender, R.M.; Bruckner, R.H. Setting up for recovery of construction and demolition waste. Solid Waste Power 1993, 7, 28–34. [Google Scholar]
  15. Tam, V.W.; Shen, L.; Fung, I.W.; Wang, J. Controlling construction waste by implementing governmental ordinances in Hong Kong. Constr. Innov. 2007, 7, 149–166. [Google Scholar] [CrossRef] [Green Version]
  16. Environmental Protection Department (EPD). Introduction to Construction Waste (2020). Available online: https://www.epd.gov.hk/epd/misc/cdm/introduction.htm (accessed on 7 May 2020).
  17. Poon, C.S. Management of construction and demolition waste. Waste Manag. 2007, 27, 159–160. [Google Scholar] [CrossRef]
  18. Poon, C.S. Reducing construction waste. Waste Manag. 2007, 27, 1715–1716. [Google Scholar] [CrossRef]
  19. Construction and Industry Council (CIC). Report on Strategy for Management and Reduction of Construction and Demolition Waste in Hong Kong Version 1, August 2017. Available online: http://www.cic.hk/files/page/56/C%26D%20Report_E.pdf (accessed on 7 April 2020).
  20. Hao, J.L.; Hill, M.J.; Shen, L.Y. Managing construction waste on-site through system dynamics modelling: The case of Hong Kong. Eng. Constr. Arch. Manag. 2008, 15, 103–113. [Google Scholar] [CrossRef]
  21. Hao, J.L.; Tam, V.W.Y.; Yuan, H.P.; Wang, J.Y. Construction waste challenges in Hong Kong and pearl river delta region. Int. J. Constr. Manag. 2011, 11, 37–47. [Google Scholar] [CrossRef]
  22. Yuan, H.; Shen, L. Trend of the research on construction and demolition waste management. Waste Manag. 2011, 31, 670–679. [Google Scholar] [CrossRef]
  23. Yu, A.T.; Poon, C.; Wong, A.; Yip, R.; Jaillon, L. Impact of construction waste disposal charging scheme on work practices at construction sites in Hong Kong. Waste Manag. 2013, 33, 138–146. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  24. Kabirifar, K.; Mojtahedi, M.; Wang, C.; Tam, V.W. Construction and demolition waste management contributing factors coupled with reduce, reuse, and recycle strategies for effective waste management: A review. J. Clean. Prod. 2020, 263, 121265. [Google Scholar] [CrossRef]
  25. Poon, C.S.; Yu, A.T.W.; Wong, S.W.; Cheung, E. Management of construction waste in public housing projects in Hong Kong. Constr. Manag. Econ. 2004, 22, 675–689. [Google Scholar] [CrossRef]
  26. Wu, Z.; Yu, A.T.; Shen, L.; Liu, G. Quantifying construction and demolition waste: An analytical review. Waste Manag. 2014, 34, 1683–1692. [Google Scholar] [CrossRef] [PubMed]
  27. Zhang, X.; Wu, Y.; Shen, L. Application of low waste technologies for design and construction: A case study in Hong Kong. Renew. Sustain. Energy Rev. 2012, 16, 2973–2979. [Google Scholar] [CrossRef]
  28. Baldwin, A.; Poon, C.-S.; Shen, L.-Y.; Austin, S.; Wong, I. Designing out waste in high-rise residential buildings: Analysis of precasting methods and traditional construction. Renew. Energy 2009, 34, 2067–2073. [Google Scholar] [CrossRef]
  29. Poon, C.S. Management and recycling of demolition waste in Hong Kong. Waste Manag. Res. 1997, 15, 561–572. [Google Scholar] [CrossRef]
  30. Lauritezen, E.K.; Hahn, N.J. Building waste generation and recycling. In International Solid Waste Management Association Year Book 1991–1992; Union of International Associations: Cambridge, UK, 1992; pp. 48–58. [Google Scholar]
  31. Li, Z.; Shen, Q.; Xue, X. Critical review of the research on the management of prefabricated construction. Habitat Int. 2014, 43, 240–249. [Google Scholar] [CrossRef] [Green Version]
  32. Jaillon, L.; Poon, C.S. Sustainable construction aspects of using prefabrication in dense urban environment: A Hong Kong case study. Constr. Manag. Econ. 2008, 26, 953–966. [Google Scholar] [CrossRef]
  33. Jaillon, L.; Poon, C.; Chiang, Y. Quantifying the waste reduction potential of using prefabrication in building construction in Hong Kong. Waste Manag. 2009, 29, 309–320. [Google Scholar] [CrossRef] [PubMed]
  34. Chiang, Y.-H.; Chan, E.H.-W.; Lok, L.K.-L. Prefabrication and barriers to entry—A case study of public housing and institutional buildings in Hong Kong. Habitat Int. 2006, 30, 482–499. [Google Scholar] [CrossRef]
  35. Tam, V.W.; Tam, C. Evaluations of existing waste recycling methods: A Hong Kong study. Build. Environ. 2006, 41, 1649–1660. [Google Scholar] [CrossRef] [Green Version]
  36. Bao, Z.; Lee, W.M.; Lu, W. Implementing on-site construction waste recycling in Hong Kong: Barriers and facilitators. Sci. Total. Environ. 2020, 747, 141091. [Google Scholar] [CrossRef] [PubMed]
  37. Osmani, M.; Villoria-Sáez, P. Current and emerging construction waste management status, trends and approaches. Waste 2019, 365–380. [Google Scholar] [CrossRef]
  38. Environmental Protection Department (EPD). A Policy Framework for the Management of Municipal Solid Waste (2005–2014). 2005. Available online: http://www.epd.gov.hk/epd/msw/htm_en/illustrations/main.htm (accessed on 31 July 2018).
  39. Ling, T.-C.; Poon, C.-S.; Wong, H.-W. Management and recycling of waste glass in concrete products: Current situations in Hong Kong. Resour. Conserv. Recycl. 2013, 70, 25–31. [Google Scholar] [CrossRef]
  40. Duan, Z.H.; Poon, C.S. Properties of recycled aggregate concrete made with recycled aggregates with different amounts of old adhered mortars. Mater. Des. 2014, 58, 19–29. [Google Scholar] [CrossRef]
  41. Lu, J.-X.; Duan, Z.-H.; Poon, C.S. Fresh properties of cement pastes or mortars incorporating waste glass powder and cullet. Constr. Build. Mater. 2017, 131, 793–799. [Google Scholar] [CrossRef]
  42. Mak, T.M.; Iris, K.M.; Wang, L.; Hsu, S.C.; Tsang, D.C.; Li, C.N.; Poon, C.S. Extended theory of planned behaviour for pro-moting construction waste recycling in Hong Kong. Waste Manag. 2019, 83, 161–170. [Google Scholar] [CrossRef]
  43. Kirchherr, J.; Reike, D.; Hekkert, M. Conceptualizing the circular economy: An analysis of 114 definitions. Resour. Conserv. Recycl. 2017, 127, 221–232. [Google Scholar] [CrossRef]
  44. Mirata, M. Experience from early stages of a national industrial symbiosis programme in the UK: Determinants and coordi-nation challenges. J. Clean. Prod. 2004, 12, 967–983. [Google Scholar] [CrossRef]
  45. Ghaffar, S.H.; Burman, M.; Braimah, N. Pathways to circular construction: An integrated management of construction and demolition waste for resource recovery. J. Clean. Prod. 2020, 244, 118710. [Google Scholar] [CrossRef]
  46. Taboada, G.L.; Seruca, I.; Sousa, C.; Pereira, Á. Exploratory data analysis and data envelopment analysis of construction and demolition waste management in the european economic area. Sustainability 2020, 12, 4995. [Google Scholar] [CrossRef]
  47. Zaman, A.U. A comprehensive review of the development of zero waste management: Lessons learned and guidelines. J. Clean. Prod. 2015, 91, 12–25. [Google Scholar] [CrossRef]
  48. Zaman, A.U.; Lehmann, S. Challenges and opportunities in transforming a city into a “zero waste city”. Challenges 2011, 2, 73–93. [Google Scholar] [CrossRef] [Green Version]
  49. DiCicco-Bloom, B.; Crabtree, B.F. The qualitative research interview. Med. Educ. 2006, 40, 314–321. [Google Scholar] [CrossRef]
  50. Gonzalez, C. Conceptions of, and approaches to, teaching online: A study of lecturers teaching postgraduate distance courses. High. Educ. 2009, 57, 299–314. [Google Scholar] [CrossRef]
  51. Guest, G.; Bunce, A.; Johnson, L. How many interviews are enough? An experiment with data saturation and variability. Field Methods 2006, 18, 59–82. [Google Scholar] [CrossRef]
  52. The Academic Triangle (20 March 2015). Available online: https://researcholic.wordpress.com/2015/03/20/sample_size_interviews/ (accessed on 3 March 2020).
  53. Gartenstein, D. Short-Term, Medium-Term & Long-Term Planning in Business; 18 October 2018. Business Ideas. Available online: https://bizfluent.com/info-8277810-shortterm-mediumterm-longterm-planning-business.html (accessed on 2 March 2020).
  54. Wu, Z.; Yu, A.T.; Shen, L. Investigating the determinants of contractor’s construction and demolition waste management behavior in Mainland China. Waste Manag. 2017, 60, 290–300. [Google Scholar] [CrossRef] [PubMed]
Table 1. Comparison of charging standards for construction waste disposal.
Table 1. Comparison of charging standards for construction waste disposal.
Disposal FacilitiesTypes Pf Construction Waste AcceptedCharge Standard in 2014 (HKD)Charge Standard in 2017 (HKD)
Public fill reception facilitiesConsisting entirely of inert construction waste2771
Sorting facilitiesContaining more than 50% by weight of inert construction waste100175
LandfillsContaining not more than 50% by weight of inert construction waste125200
Table 2. Barriers and difficulties in construction waste management.
Table 2. Barriers and difficulties in construction waste management.
Barriers/DifficultiesCauses
Clients’ low incentiveLabor and time consuming, which incur high initial cost deter clients to consider adopting waste management practices.
Composite site conditionInsufficient space for on-site sorting and temporary storage of sorted waste.
High recycling costLabor and transportation costs of recycling construction waste are high particularly for timber and concrete.
Quality of recycled materialsLacking standardization of quality.
Immature recycling marketThere are few local recycling companies especially for timber and concrete resulting in high recycling costs
Insufficient skilled laborsInsufficient skilled labors to handle aluminum formwork.
Illegal dumpingSome public filling areas are too remote and under-utilized.
Penalties of illegal dumping are insignificant comparing to contract sums.
Inadequate government support to green technologyConservative attitude of Government in approving innovative green technologies.
Lengthy and complicated approving procedure.
Influence of BEAM PlusThe low achievement to satisfy the stringent requirements of 60% of recycling construction waste for accrediting only 2 credits.
Discouraging minimizing use of steel, reuse excavated soil for backfilling, revitalize and reuse existing foundation and structural framework, revise method statement according to site conditions for reducing abortive work as these attempts are not considered for accreditation.
Lack of monitoring system for compliance with accreditation requirements.
Table 3. Suggestions for improving construction waste management.
Table 3. Suggestions for improving construction waste management.
Findings from Literature ReviewSuggestions from InterviewsSuggestions from Focus Group Meetings
Design StageDimensional coordination, standardization,
design for use of recycled materials, avoiding late design modifications and modeling design information, use of prefabrication
Consider using waste-reducing design and technologies early in the design stage.
Use “integrated project design” involving multi-disciplines to reduce abortive work.
Apply BIM to reduce crashes in construction processes.
Apply adaptable design, no-frill design, use precast and prefabrication technologies, standard and modular units.
Reuse existing building foundation and structure.
Use reusable formwork, sustainable and recycling materials, and drywall systems.
Tender StageWaste management plansIntroducing contractual “recycle rates” and “Award and Penalty Scheme” in the tender document.
Allow contractors to propose EMP and award contactors for meeting defined goals.
Penalty for noncompliance.
Using “Design and Build” contracts in infrastructure projects to help formulate custom-designed WMP to suit site conditions.
A percentage of contact sum to be set aside as a bonus award to contactors for meeting targeted goals in construction waste management.
Construction StageMinimizing the use of temporary works, applying low-waste building technologies, backfilling cut and fill by the excavated soils,
On-site sorting and off-site sorting
Allow longer construction periods for implementing WMP.
Carry out construction work in phases to facilitate reusing temporary works.
Setting up communication platforms among contractors for coordinating reuse and recycling construction waste.
Clients should allow sufficient time for the application of Occupation Permit to avoid using temporary provisions to satisfy the issuing requirements.
Government SupportConstruction waste disposal charging schemePromote the application and development of green construction technologies and materials.
Encourage contractors to reuse/recycle construction waste.
Facilitate local development of recycling and prefabrication industries.
Public education on the importance of reducing and recycling construction waste.Public consultation to collect suggestions for effective construction waste management.
Provide low-rent sites for setting up the prefabrication industry.
To utilize incinerator at Tuen Mun for burning timber waste or allow the use of waste-derived fuel in the industry.
Building Department to consider re-classifying extensive reuse of existing building under New Building category to encourage revitalization projects.
Create more public off-site sorting spaces.
Privatize the management of the current government-run waste sorting sites enabling market forces to initiate the development of the recycling industry.
Create a variety of recycling outlets.
Large-scale increase in waste disposal charges suggested being HKD 500/ton.
Coordinate with CIC and Hong Kong Green Building Council (HKGBC) to streamline the approval of low-waste technologies and reusable materials.
HKGBC to review BEAM Plus accreditation for reducing construction waste in a passive manner.
To standardize the quality of recycled materials
Table 4. Proposed strategies for construction stakeholders.
Table 4. Proposed strategies for construction stakeholders.
MeasuresClientDesignerContractorImplementation Time Frame
Design Stage
No-Frills DesignXX M
Adaptive designXX M
Integrated Project Design XXM
Consider waste reduction and managementXX M
Use Design and Build contract for infrastructure projectsXXXM
Low-waste technologiesXX S/M
Use precast concrete/prefabricated building componentsXX S
Reuse existing foundation/structuresXX S
Use reusable temporary work X S
Use dry wall system and external paintingXX S
Use durable/recycled building materialsXX S
Minimize design revisionXX S
Apply BIM to review construction sequences X S
Tender Stage
Introduce “Award and Penalty” schemeXXXM
Contractors propose innovative waste management schemeXXXM
Introduce waste reduction procurement for nominated subcontractsXXXM
Allow recycling rates in BQXXXS
Construction Stage
Setup contractor communication platform for reuse and recycling XL
Allow longer construction periodX M
Review Method Statement for Construction XXM
Better phasing construction period XXS
Onsite/off-site sorting XS
Consider off-site sorting when onsite sorting is not feasible XS
Reuse excavated soil in other projects XS
Reuse demolished concrete for paving bicycle tracks XS
S = short term; M = medium tern; L = long term.
Table 5. Proposed measures for government/public organizations to reduce construction waste.
Table 5. Proposed measures for government/public organizations to reduce construction waste.
Proposed ActionsImplementation Timeframe
Interim Measures
Use waste to energy technology to burn timber waste for energy recovery.S
Promote green technologies and materials
Setup a central coordinating team for approving alternative recyclable/reusable materials.M
Simplify and streamline the approval process of innovative waste-reducing technologies.M
Streamline approving process of low-waste technologies and reusable materials.M
Encourage reuse/recycling of C&D waste
Significant increase in waste disposal charges.S
Mandate selective onsite sorting for timber and plastic wastes.M
Mandate the use of reusable formworkM
Introduce stronger incentives to encourage the recycling of construction waste in green building rating schemes.M
Set up C&D waste reduction policy and monitor implementation.L
Set up recycle standards and study implementation methods.L
Help explore potential markets on recyclable materials.L
Review and revise the scoring system of the green building rating system.L
Facilitate the development of the recycling industry
Streamline and simplify the approval process of recycling subsidies.M
Provide more public waste sorting sites.M
Privatize the sorting facilities to let the market decide the appropriate development patterns.L
Publicize the potential of lining up with recycling factories in Mainland China.L
Facilitate the development of local prefabrication industry
Award Gross Floor Area concession for precast/prefabricated façade.M
Provide low-rent sites for manufacturing.M
Research and Education
Set up research funding for construction waste reduction and management.L
Educate clients and contractors on the social responsibility of reducing construction waste.L
Educate the general public on the importance and necessity to minimize construction waste.L
S = short term; M = medium tern; L = long term.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Yu, A.T.W.; Wong, I.; Wu, Z.; Poon, C.-S. Strategies for Effective Waste Reduction and Management of Building Construction Projects in Highly Urbanized Cities—A Case Study of Hong Kong. Buildings 2021, 11, 214. https://0-doi-org.brum.beds.ac.uk/10.3390/buildings11050214

AMA Style

Yu ATW, Wong I, Wu Z, Poon C-S. Strategies for Effective Waste Reduction and Management of Building Construction Projects in Highly Urbanized Cities—A Case Study of Hong Kong. Buildings. 2021; 11(5):214. https://0-doi-org.brum.beds.ac.uk/10.3390/buildings11050214

Chicago/Turabian Style

Yu, Ann T. W., Irene Wong, Zezhou Wu, and Chi-Sun Poon. 2021. "Strategies for Effective Waste Reduction and Management of Building Construction Projects in Highly Urbanized Cities—A Case Study of Hong Kong" Buildings 11, no. 5: 214. https://0-doi-org.brum.beds.ac.uk/10.3390/buildings11050214

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop