View Article

Abstract

This paper presents a comprehensive review of the financial sustainability of construction and demolition (C&D) waste recycling plants, addressing critical aspects such as economic viability, cost-effectiveness, revenue generation models, investment strategies, and market dynamics. The review underscores the environmental challenges posed by C&D waste, which constitutes over 30% of global solid waste, and highlights the importance of effective management and recycling in mitigating resource depletion and pollution. The study evaluates key financial factors, including operational costs, market demand for recycled products, and the role of government incentives, revealing that despite financial hurdles, there are significant revenue opportunities in the sale of recycled materials and value-added products. Case studies demonstrate that with adequate policy support and integration into circular economy frameworks, recycling plants can achieve long-term profitability. The findings emphasize the potential of circular economy strategies to enhance financial sustainability by reducing raw material costs, improving resource efficiency, and promoting waste valorization. The study concludes that a balanced approach, combining technological innovation, strong regulatory frameworks, and increased public awareness, is essential for advancing the financial performance and sustainability of C&D waste recycling plants. This review contributes valuable insights into optimizing the financial sustainability of recycling initiatives, supporting the transition to more sustainable construction practices.

Keywords

Construction and Demolition Waste, Financial Sustainability, Waste Management, Recycling Plants, Sustainability Criteria.

Introduction

Due to the rapid pace of urbanization and the corresponding rise in construction activities, which result in substantial waste generation, construction and demolition (C&D) waste management has become a critical global issue. Recycling plants that process C&D waste are essential for minimizing environmental impacts, conserving natural resources, and promoting sustainable development. However, despite their importance, stakeholders, including investors, policymakers, and environmentalists, are concerned about the financial sustainability of these recycling plants. Technological advancements, such as automated sorting systems, creative recycling processes, and data-driven decision-making tools, have improved the efficiency and profitability of these facilities, making them more viable.(Ibrahim et al., 2024).

Construction and demolition (C&D) waste is one of the most important waste flows, accounting for 30% to 40% of all urban waste generated, and is a byproduct of construction, renovation, and demolition activities. (Wang, 2004). Every year, a few large nations produce about 10 billion tonnes of C&D garbage. China is the largest contributor, accounting for around 3 billion tonnes, owing to its extensive urbanization and urban redevelopment initiatives.

(Zheng, 2017). In contrast, the US and the EU produce 700 million and over 800 million tonnes, respectively (EC, 2016). Numerous negative effects on society and the environment, including land occupation, raw material and energy consumption, greenhouse gas emissions, and water contamination, are brought on by the massive output of C&D waste.
One of the major sectors influencing a nation's social and economic development is the construction sector. By giving society access to socioeconomic projects and infrastructure like roads, hospitals, and schools, it raises the level of living for the community. Regrettably, CDW, or building and demolition waste, is becoming a global problem.(Hussin J, 2013).

Recycling garbage from construction and demolition (C&D) projects is essential for reducing the negative environmental effects of the construction sector since it keeps waste out of landfills and encourages resource efficiency. However, in order to make sure that the operations of C&D waste recycling plants are in line with social, economic, and environmental goals, it is crucial to evaluate the sustainability of these facilities. This assessment includes a thorough examination of numerous aspects, such as the use of resources, methods for managing waste, energy use, emissions, and socioeconomic effects.(Hussin J, 2013).

Waste management is a method that is developed to optimize dwindling world resources. In this regard, studies were conducted primarily, (Villalba, 2002).Iin order to assess the recyclability of materials more than 20 years ago. But as the idea of the circular economy was refined later, these studies began to gather steam. (Huysman, 2017). Within this developing process, waste types were divided into domestic, industrial, agricultural, construction and demolition, hazardous, medical, and special waste (Ferronato, 2019). Examining these wastes reveals that one industry that affects the environment and requires proper management is construction and demolition waste (commonly referred to as CDW). Urban regeneration and transformation are two major factors contributing to the waste generated during construction and destruction.  (Yazdani, 2021). The existing buildings must be renovated in order to make room for the growing population, and new construction must be sustainable to avoid a repeat of the current state of affairs. (Y?ld?z, 2020). Cities around the world are changing due to physical, social, and cultural transformations. Cities compete fiercely with one another as a result in many different ways. Cities seek to innovate and transform physical space in this race, viewing the process of urban development as an opportunity. Urban transformation revitalizes the city's abandoned rift areas, promotes healthy and efficient development, fortifies the city's economy, and raises the standard of living in the community. (Hölscher, 2021).  This paper aims to provide a comprehensive review of the financial sustainability aspects of construction and demolition waste recycling plants. By evaluating key factors such as economic viability, cost-effectiveness, revenue generation models, investment strategies, and market dynamics, this review seeks to contribute valuable insights into enhancing the financial performance and long-term viability of C&D waste recycling initiatives. Recent studies have highlighted the importance of integrating circular economy principles into waste management strategies, emphasizing the potential for cost savings, resource efficiency, and environmental benefits. For instance, demonstration on how circular economy strategies can improve the financial sustainability of recycling plants by reducing raw material costs and enhancing waste valorisation.

Review of Related Literature

The Table below summarizes and represents some of the relevant literatures consulted for this study:

 

S/N

Author(S) & Journal name

Tittle

Methodology

Main Findings

Research Gap/ Limitations

01

(Serdar Ulubeylia, 2017)

Journal of Elsevier

Construction and Demolition waste recycling plants revisited: management issues

Review

Management issues can be classified as economics, environments, location and administration. Finally, as a social implication better management C&DW recycling plants can and enhance the sustainability of the overall environment and effect society positively.

 Lack of comprehensive examination of management issues in construction and demolition waste (C&DW) recycling facilities.

02

(G. Rodríguez, 2014)

Journal of Elsevier

Assessment of C&DW plants management in Spain: In pursuit of sustainability and eco-efficient

The research was based on collection, interpretation of data gathered in a survey conducted in 2012 and 2013

 European waste management policies emphasize the importance of effectively managing this type of waste to mitigate the environmental impacts associated with its disposal.  

 There is need for a reassessment of the current management model for construction and demolition waste (C&DW) recycling plants in Spain.

03

 (Shan-shan Chung, 2003)

Journal of Elsevier

 

 

Evaluating sustainability in waste management: the case of Construction and Demolition, Chemical and Clinical wastes in Hong Kong

Literature review on environmental desirability, economic optimization, social acceptability and equity and administrative diligence.

The management of C&DW, clinical waste, and chemical waste in Hong Kong falls short of sustainability criteria. Despite the urgent need for sustainability, the analysis reveals deficiencies in environmental impact control, economic optimization, social equity, and administrative diligence.

Hong Kong's Clinical waste management is satisfactory, other areas like construction waste lack proper economic strategies.

04

 (Huanyu Wua, 2019)

 

Journal of Elsevier

A review of performance assessment methods for construction and demolition waste management

It reviews existing literature, focusing on data collection methods.

 Understanding the effectiveness of models used for assessing construction and demolition waste management (CDWM) performance.

This research identifies gaps in CDWM performance assessment.

 

 

05

 (Haya Hussain, 2023)

International Journal for Research in Engineering Application and Management (IJREAM)

Construction and Demolition Waste Management

Review

The paper emphasizes the importance of addressing waste management issues to mitigate the serious negative effects of trash on the nation. It discusses the 3R concept (reuse, reduction, and recycling) as a key approach.

The research gap in this study is the lack of specific exploration into the unique challenges and contextual factors of waste management in India, as well as the absence of in-depth analysis on existing policies and practical solutions relevant to the Indian context.

06

 (Leonidas Milios, 2010)

Journal of MDPIS

Sustainability Impact Assessment of Increased Plastic Recycling and Future Pathways of Plastic Waste Management in Sweden

By using model analysis that calculates environmental, economic, and social impacts

This paper emphasizes the importance of high recycling targets and phasing out plastic incineration to promote sustainability and mitigate environmental harm.

Lacks detailed analysis on the feasibility and practical implementation of proposed policy measures.

07

 (Dima W. Nazer, 2010)

Journal of Springer

A Financial, Environmental and Social Evaluation of Domestic Water Management Options in the West Bank, Palestine

By using the concept of life cycle impact assessment (LCIA).

This Research indicate that domestic water management options, evaluated economically, environmentally, and socially using LCIA, have the potential to significantly reduce water consumption by over 50% in Palestinian conditions.

It suggests significant water consumption reductions and highlights financial attractiveness.

08

 (Navarro Ferronato, 2023)

Journal of Springer

Construction and demolition waste recycling in developing cities: management and cost analysis

The Research is carried out by the use of secondary data

The issue of CDW in Bolivia and across Latin America is commonly disposed of in open dumping areas. Brazil, Peru, and Mexico face similar challenges, with inadequate CDW management despite bans on open dumping and lack of legislation encouraging recycling.

.

There's an urgent need for implementing proper CDW management systems throughout Latin America to address environmental and health concerns

09

(Ahmed Osama Daoud, 2023)

Analysis of factors affecting construction and demolition waste reduction in Egypt

Quantitative Research Approach using Survey Questionnaire

The study investigates construction waste in Egypt and identifies six factors affecting waste reduction. It finds that while some practices like correct material purchase are common, others like reducing material use through prefabrication are more effective.

Lack of depth in understanding implementation challenges and it fails to provide practical guidance on implementing solutions, leaving a gap in knowledge regarding effective strategies for the Egyptian construction sector.

 

 

10

(Ogulcan Yazgan, 2023)

Construction and Demolition Waste Management in Urban Transformation: A Case Study for Performance Evaluation

Using Analytical Hierarchy Process (AHP) and Gray Relations Analysis (GRA), it assesses the performance of public and private companies in this sector.

The research provides insights into the recycling of construction and demolition wastes in Turkey, evaluates company performance, and suggests strategies for improvement, with broader applicability to the construction industry.

Lack of identification of strengths and weaknesses is limited by its broad approach to the construction sector and general evaluation criteria."

11

(K.R.A. Nunes, 2006)

Evaluation of investments in recycling centres for construction and demolition wastes in Brazilian municipalities

Involved a combination of literature review, expert consultation, data and financial analysis techniques.

The findings provide valuable decision-making support for investing in recycling infrastructure in Brazil and similar developing countries.

The research gap in the lack of economic evidence supporting sustainable management of construction and demolition (C&D) waste in Brazil.

12

(Lai Sheung Au, 2018)

System Dynamic Analysis of Impacts of Government Charges on Disposal of Construction and Demolition Waste: A Hong Kong Case Study

Review

The paper introduces a system dynamics model to evaluate the effects of construction and demolition waste disposal charges (CDWDC) using Hong Kong as a case study.

The model needs refinement in incorporating dynamic charging schemes and validating assumptions about waste accumulation.

13

(Castorina Silva Vieira, 2015)

Use of recycled construction and demolition materials in geotechnical applications: A review

Conducting a literature review on the use of Construction and Demolition (C&D) materials in geotechnical engineering applications

This paper underscores the importance of sustainable development by advocating for proper management and recycling of Construction and Demolition (C&D) wastes.

The research suggests the need for blending certain recycled C&D materials with other aggregates for optimal performance, indicating a necessity for additional research and optimization efforts in this field.

14

(Juan A Ferriz-Papi a, 2022)

A cost-effective recycled aggregates classification procedure for construction and demolition waste evaluation

Use of the Aggregate Potential (Physical) (AP(P)) scale to characterize recycled aggregates from construction and demolition waste

The results revealed varying quality ratings of the aggregates, suggesting different potential uses and recommending simple treatments for higher value applications.

The Research gaps and limitations underscore the complexity of evaluating and utilizing recycled aggregates from C&D waste and suggest areas for further research and improvement in both procedures and manufacturing processes.

15

(Silvia Iodice, 2021)

Sustainability assessment of Construction and Demolition Waste management applied to an Italian case

By using local primary data, and complementing them with data from literature and datasets.

the study underscores the potential environmental and social advantages of adopting selective demolition and best practices in CDW management.

The study lacks detailed strategies to address these costs and broader socio-economic implications.

 

KEY CONSIDERATIONS

Construction and Demolition Waste (C&D Waste)

Construction and demolition (C&D) waste encompasses the debris produced during the construction, renovation, and demolition of buildings, roads, and bridges, and includes a range of materials that are typically heavy and bulky. Defined as solid waste generated in the building and construction industries, C&D waste includes both construction waste, which arises during the erection and renovation of structures, and demolition waste, which comes from dismantled buildings and other structures. This waste stream is a significant component of global solid waste, accounting for over 30% of the total waste generated worldwide. C&D waste management (C&DWM) involves a series of activities required to handle this waste from its initial generation to its final disposal or effective utilization. This includes managing waste from civil works, site clearance, road construction, land excavation, grading, and demolition activities. Environmental disasters such as floods, earthquakes, and hurricanes also contribute to massive amounts of C&D waste. Typical materials found in C&D waste include rock, masonry, asphalt, metals, sand, plastics, asbestos, plasterboard, and cardboard. The large volume of C&D waste generated annually highlights the need for effective waste management strategies to mitigate environmental impacts and promote recycling and reuse.(Elshaboury et al., 2022).

Types of C&D Waste

  1. Concrete

Concrete is the most popular building material, (Ubayi, Ahmad, et al., 2024). It is primarily a composition of cement, coarse aggregates, fine aggregates and water, further processed by addition of industrial products/ by products for enhancing the properties. Engineers are mainly dependent on nature for obtaining the Coarse and Fine aggregates as well as water for the chemical reaction with cement. (Ubayi, Ahmad, et al., 2024). Scarcity is there for all these naturally occurring materials and need is there to explore alternative sources. Even for the water with required properties, shift is towards the use of waste water after due treatment. One of the alternative sources of coarse aggregates is recycled concrete aggregates (RCA) which are obtained from the processed Construction and Demolition (C&D) waste. During and after the demolition of any concrete structure, the demolished concrete waste is taken to a recycling plant and there crushed into the required sizes which is called the Recycled concrete aggregate (RCA). Sometimes, good sized precast element is also obtained during the demolition, which have a potential of being reused or otherwise, these are also crushed and converted into the recycled aggregates. Thus, use of recycled aggregates can be there with different quantum of their share by suitable replacing the component of naturally occurring aggregates. It will help out not only in meeting the situation where there is acute shortage of natural resources, but also a step towards the sustainability. (Bansal & Singh, 2014)

  1. Bricks

Bricks are a fundamental building material in both residential and non-residential construction worldwide, and they also constitute a significant portion of construction and demolition (C&D) waste. Their demand is second only to concrete, yet bricks are often discarded as waste when broken, damaged, or mishandled during production or construction. Despite this, bricks are highly durable, requiring minimal maintenance over a building's life, and their environmental friendliness is underscored by their reusability after demolition. Buildings typically aren't demolished due to the deterioration of brick's engineering properties, but rather for other reasons, such as outdated design or the need for a new structure. During demolition, bricks can be salvaged, cleaned of mortar, and reused in their original form or recycled into aggregates or brick chips for construction materials. Recovered bricks can serve as fresh building materials, be used in landscaping, or as pavement solutions, offering aesthetic and functional benefits like rainwater percolation and cooler surfaces in hot weather. Even bricks that can't be reused directly can be recycled into road bases, construction fill, or lightweight concrete, demonstrating strong and durable properties. Additionally, brick waste from manufacturing defects can be recycled similarly to C&D waste, finding new life in precast elements like paver blocks and interlocking tiles, thus contributing to sustainable building practices.  (Bansal & Singh, 2014).

  1. Tiles

Extracting tiles from walls in proper shape and size for reuse is generally challenging, depending on the type of tiles, their lifespan, and existing conditions. Despite this difficulty, even broken tile pieces offer significant opportunities for artists and designers to create murals or decorative masterpieces. Broken tiles can also be crushed and used as aggregate in construction. When tiles are removed intact, they can be reused for their original purpose after cleaning off any stuck mortar and applying suitable adhesives available in the market. These tiles can be creatively repurposed into artifacts, table tops, special effects in driveways, pedestrian subways, and a variety of other projects. A renowned example of such reuse is Nek Chand’s Rock Garden in Chandigarh, which showcases the artistic potential of discarded materials. Additionally, broken tiles can be further crushed into smaller sizes and used as a partial replacement for gravel and crushed stone in concrete, contributing to sustainable construction practices.  (Bansal & Singh, 2014).

  1. Timber

Waste timber is generated not only from the demolition of buildings but also during the construction of wooden structures, with each source requiring its own system of recycling and reuse. When a building is dismantled, timber products like doors and windows are typically removed first, often in their original form, due to their long service life, which frequently exceeds the lifespan of the building itself. Unless significantly damaged by termites or fire, timber retains its engineering properties over time, making it an environmentally friendly material that can be reused multiple times. Timber that cannot be recovered in its original form or is unsuitable for reuse can still be recycled into new products, such as particleboard, medium-density fibreboards, or animal bedding, or it can be used to generate renewable energy. For recycling, timber must be free of contaminants like concrete, mortar, aggregates, sand, bricks, plastic, metals, and tiles. High-quality wooden waste, such as large lumber, is often chipped and used by companies that produce particleboard, pulp, and paper. Additionally, chipped or shredded wood serves various purposes, including as a sewage sludge bulking medium and in the production of pallets, highlighting the versatility and sustainability of recycled timber.  (Bansal & Singh, 2014)

  1. Metals

Steel and aluminium are the two predominant metals that become waste products during both the construction and demolition of buildings. Structural steel, often recovered from demolished steel structures or leftover from construction, can be reused directly with minimal processing; it can be resized as needed, preserving its integrity and saving energy that would otherwise be required for re-melting and rolling new beams. Similarly, aluminium scrap, which can be recycled through solid bonding processes, offers substantial reuse potential if a thoughtful deconstruction plan is implemented from the design phase, minimizing the need for processing through a foundry. Steel waste generated during construction and demolition is typically easy to collect and segregate for recycling, resulting in minimal on-site waste and maintaining high durability and quality for new products like fire hydrants and steel furniture. Aluminium, known for its infinite recyclability, requires significantly less energy to recycle compared to producing new aluminium from bauxite ore, and can be reused in various applications, from household items to high-end products. Its ability to be recast into its original form or used in new ways underscores its sustainability and ongoing demand, making it an ideal material for environmentally conscious recycling practices.  (Bansal & Singh, 2014).

  1. Plastic

Scrap or waste plastic recovered from demolition or construction sites undergoes reprocessing to be transformed into a variety of useful products, although it is typically not recycled into the same type of plastic, and products made from recycled plastics often cannot be recycled again. Compared to materials like glass and metals, plastic polymers require more extensive processing for recycling. High-density polyethylene (HDPE), one of the most commonly recycled plastics, is often converted into products such as plastic lumber, tables, roadside curbs, benches, and stationery items like rulers, all of which are durable and in high demand. Another innovative application of recycled plastic involves its use in road surfaces, where shredded and melted plastic, combined with aggregate and bitumen (asphalt), is applied to create roads. These surfaces, processed at temperatures below 220°C (428°F) to minimize pollution, are known for their durability and resistance to monsoon rains, demonstrating the potential for recycled plastic to contribute to sustainable infrastructure solutions.  (Bansal & Singh, 2014).

Impact of C&D Waste on Environment

The impact of construction and demolition (C&D) waste on the environment is profound, contributing to a range of serious ecological issues. The construction industry, while essential for societal progress, is a major source of environmental degradation, leading to resource depletion, pollution, and exacerbation of climate change. Building activities are responsible for significant CO2 emissions, largely due to the use of non-renewable resources during construction and throughout the lifespan of structures. These emissions have been a driving force behind global warming and the resulting climatic changes. Additionally, C&D activities generate considerable dust and noise, which not only degrade air quality but also pose severe health risks, particularly for individuals with respiratory conditions. The situation is further worsened by the disposal practices in industries such as marble processing, where millions of tons of waste are generated annually, leading to soil infertility, waterlogging, and the spread of hazardous dust in the environment. Urban pollution, particularly in India, is heavily influenced by road dust from C&D waste, which significantly contributes to particulate matter levels that are harmful to human health. Moreover, the construction industry’s use of pollutant fluids like paints and solvents can lead to land contamination unless managed carefully. While more sustainable alternatives exist, they are often more expensive, highlighting the need for stringent C&D waste management and the adoption of sustainable construction practices to mitigate these environmental impacts (Gupta & RK, 2018).

Financial Challenges in Construction and Demolition (C&D) Waste Recycling

The construction and demolition (C&D) waste recycling industry faces several significant financial challenges that can impact its overall sustainability and profitability. The financial challenges in Construction and Demolition (C&D) waste recycling are significant and multifaceted, often hindering the effectiveness and sustainability of these practices which include: (Al-Raqeb, Ghaffara, Al-Kheetan, & Chougan, 2023).

  1. High Costs of Recycling: The process of recycling C&D waste is often costly, particularly when considering the expenses related to sorting, transportation, and processing. These costs can outweigh the value of the recycled materials, making it economically unviable for many projects?.
  2. Limited Market for Recycled Materials: There is often a lack of an established market for recycled construction materials, which leads to limited demand. This immaturity in the market is compounded by negative stakeholder attitudes and the higher costs associated with recycled materials compared to virgin materials.
  3. Economic Uncertainty: Economic uncertainty is a major deterrent to adopting sustainable practices in C&D waste management. This uncertainty can stem from fluctuating market conditions, policy changes, and the unpredictable nature of construction projects, all of which contribute to financial instability in recycling efforts.
  4. Logistical Barriers: The logistics of transporting C&D waste to recycling facilities can be costly and complex. Inefficient logistics can lead to increased costs and environmental damage, as well as disruptions in recycling operations?.

Economic Viability and Cost Analysis

The economic viability of a construction and demolition (C&D) waste recycling facility is determined by a comprehensive cost analysis that includes both fixed and variable costs. Fixed costs cover essential investments in land, site development, building works, machinery, vehicles, and auxiliary services, all crucial for establishing the facility and ensuring it is operationally ready. Operating costs include ongoing expenses such as energy, maintenance, salaries, transportation, and administrative overheads. Revenue generation can come from various sources, including gate fees from waste generators, the sale of recycled materials like aggregates and metals, and the potential sale of by-products such as silt or incinerable waste. The financial sustainability of such a facility is often measured by the payback period, which depends on the balance between these costs and the revenue streams, as well as market demand for recycled products. A case study of a C&D waste recycling plant in Delhi demonstrated that with high waste generation rates, elevated prices for virgin materials, and government support, the facility achieved a payback period of about ten years. This indicates potential financial viability, though further improvements in taxation policies and market stability could enhance profitability.(Thakur et al., 2022).

The financial challenges in construction and demolition waste (CDW) management involve high recycling costs that exceed the value of recovered materials, making recycling less attractive compared to using cheaper virgin materials. Logistical issues, such as transportation disruptions, and a weak market for recycled materials further complicate the process. Overcoming these barriers requires better awareness, stronger regulations, and improved supply chain management to make CDW recycling more economically viable. (Al-Raqeb, Ghaffar, Mazen, & Chougan, 2023).

Revenue Streams and Market Opportunities

The various revenue streams and market opportunities for C&D waste recycling plants. These include: (Thakur et al., 2022).

1. Sale of Recycled Products: The primary revenue stream for C&D waste recycling plants comes from the sale of recycled materials like aggregates, sand, and other construction materials. These products can be sold to construction companies at competitive prices compared to virgin materials, especially in regions where natural resources are scarce or expensive.

2.Government Incentives and Subsidies: Government policies that encourage recycling, such as tax incentives, subsidies for recycling infrastructure, and preferential treatment in public contracts, can create additional revenue streams. These policies can also lower the operational costs of recycling plants, making them more financially viable.

3. Market Demand for Sustainable Products: As the construction industry increasingly focuses on sustainability, there is a growing market for eco-friendly building materials. Recycled products can tap into this demand, especially in green building projects and certifications like LEED, which encourage the use of recycled materials.

4. Diversification of Products: C&D waste recycling plants can diversify their product lines to include value-added products like precast concrete elements, bricks, and tiles made from recycled materials. This diversification can open up new market opportunities and increase profitability.

5Waste Management Contracts: Securing long-term contracts with municipalities, construction companies, and developers for the collection and processing of C&D waste can provide a steady revenue stream. These contracts can also help stabilize cash flow and reduce financial risk.

6. Export Opportunities: In some cases, there may be opportunities to export recycled materials to countries or regions with high demand for construction materials but limited natural resources. This can create additional market opportunities for C&D waste recycling plants.

Policy and Regulatory Impacts

Policy and regulatory frameworks significantly influence the operation and financial sustainability of construction and demolition (C&D) waste recycling plants. Government policies and regulations shape the industry by setting standards, providing incentives, and imposing requirements that can affect both the cost structure and operational practices of recycling facilities.

The policy and regulatory impact on the financial sustainability of construction and demolition (C&D) waste recycling plants is significant, especially within the Indian context. Despite the Ministry of Environment, Forest, and Climate Change's publication of the C&D Waste Management Rules in 2016, only about 1% of India's C&D waste is currently recycled. The primary challenge in expanding recycling capacity is the lack of viable business models due to insufficient policy support, which discourages entrepreneurs from investing in such facilities.

The rules emphasize the responsibilities of waste generators, local authorities, and private operators. Waste generators must segregate and store C&D waste, while local authorities are tasked with providing and maintaining Local Collection Points (LCPs). However, the success of C&D waste recycling plants heavily depends on further policy initiatives. These could include rationalizing taxes on recycled products, ensuring an assured market for these products, and facilitating risk-sharing between stakeholders. Additionally, steps such as reducing power tariffs and providing land at nominal costs could enhance the financial viability of these plants (Thakur et al., 2022).

Sustainability and Environmental Considerations

Sustainability and environmental considerations are central to the effective management of Construction and Demolition (C&D) waste. Recycling C&D waste not only reduces the volume of waste sent to landfills but also conserves natural resources by reusing materials like concrete, metals, and timber. This process minimizes the environmental footprint of construction activities by lowering the demand for new raw materials, reducing energy consumption, and decreasing greenhouse gas emissions associated with the production and transportation of these materials. (Ubayi et al., 2024)

Incorporating sustainable practices in C&D waste management also helps in mitigating environmental degradation. By promoting the use of recycled materials in new construction projects, the need for virgin materials is reduced, which in turn helps in preserving natural landscapes and reducing the exploitation of non-renewable resources. Additionally, recycling C&D waste contributes to the circular economy, where materials are kept in use for as long as possible, maximizing their value and reducing the overall environmental impact. Moreover, effective C&D waste recycling can help in managing environmental hazards. Proper disposal and recycling of hazardous materials like asbestos, lead, and treated wood prevent these substances from contaminating soil and water, thus protecting ecosystems and human health. Implementing stringent environmental standards and encouraging the use of recycled materials in construction can significantly enhance the sustainability of the industry, leading to long-term ecological benefits.(Thakur et al., 2022).

FUTURE TRENDS AND INNOVATIONS

The future trends and innovations in the context of construction and demolition (C&D) waste recycling: (Thakur et al., 2022).

1. Increased Recycling Capacity and Technological Advancements: There is a significant push towards increasing the capacity of C&D waste recycling plants and enhancing the technology used in these plants. This includes advancements in recycling processes that could lead to higher quality recycled materials, making them more competitive with virgin materials.

2. Government Policy and Regulatory Support: Future trends include stronger regulatory frameworks and policies to support the financial viability of C&D waste recycling. This may involve tax incentives, mandatory recycling quotas, and stricter enforcement of C&D waste management rules.

3. Public Awareness and Market Demand: Efforts to raise public awareness about the environmental benefits of using recycled C&D materials are expected to grow. This includes promoting the use of recycled products in public and private construction projects, which could increase demand and make recycling more profitable.

4. Circular Economy Integration: A major innovation trend is the integration of C&D waste recycling into a broader circular economy framework. This involves designing buildings and infrastructure with future recycling in mind, as well as creating closed-loop systems where materials are continually reused.

Discussion of Findings

Construction and Demolition (C&D) waste, encompassing materials like concrete, bricks, tiles, timber, metals, and plastics, represents a significant environmental challenge due to its sheer volume and diverse components. Comprising over 30% of global solid waste, C&D waste demands effective management to mitigate its ecological impact. Concrete, a major building material, is increasingly recycled into aggregates to address resource scarcity and promote sustainability.  Bricks, known for their durability, can be salvaged or recycled into new aggregates, thus supporting sustainable construction practices. Tiles, whether intact or broken, offer opportunities for creative reuse and recycling, as exemplified by the Rock Garden in Chandigarh. Timber, versatile and eco-friendly, can be repurposed into new products or used as an energy source, while metals like steel and aluminium, which are highly recyclable, maintain their durability and reduce production-related emissions. Plastic waste, though challenging to recycle into the same type, finds innovative applications in products like road surfaces, demonstrating its role in sustainable infrastructure.

The environmental impact of C&D waste is substantial, contributing to resource depletion, pollution, and climate change. The construction sector’s significant CO2 emissions, along with air quality degradation and soil contamination from dust and marble processing waste, highlight the urgent need for improved waste management. Financially, recycling C&D waste faces challenges including high costs, limited market demand for recycled materials, economic uncertainty, and logistical barriers. Despite these obstacles, enhancing the economic viability of recycling facilities can be achieved through increased awareness, stronger regulations, and improved supply chain management. Case studies, such as those from Delhi, show that with high waste generation rates and government support, a payback period of approximately ten years can be achieved, indicating potential profitability. Overcoming these financial and environmental challenges through sustainable practices and effective policies is crucial for advancing C&D waste recycling and reducing its ecological footprint. Revenue streams and market opportunities for C&D waste recycling offer potential benefits for the industry. The sale of recycled products like aggregates and sand can provide substantial revenue, particularly in areas with scarce natural resources. Government incentives and subsidies can further enhance financial viability by lowering operational costs. As demand for sustainable construction materials grows, driven by certifications such as LEED, recycled products are becoming more prominent in the market. Diversifying into value-added products, such as precast concrete elements and recycled bricks, opens new market opportunities and boosts profitability. Long-term waste management contracts with municipalities and construction firms can stabilize revenue and cash flow, while exporting recycled materials to regions with high demand but limited natural resources offers additional opportunities.

However, policy and regulatory frameworks play a crucial role. In India, despite the C&D Waste Management Rules of 2016, only a fraction of C&D waste is recycled due to inadequate policy support. Strengthening regulations, including rationalizing taxes on recycled products, ensuring market demand, and providing financial incentives, is necessary. Sustainability and environmental considerations are central to effective C&D waste management, reducing landfill use, conserving resources, and lowering greenhouse gas emissions. Future trends indicate a shift towards expanding recycling capacities, adopting advanced technologies, and integrating recycling into a circular economy framework, supported by increased public awareness and supportive policies to drive economic and environmental sustainability.

Key Factors Affecting Financial Sustainability

1. Operational Costs: Investigate the key operational costs associated with recycling plants, including labour, energy, transportation, and maintenance.

2. Revenue Streams: Analyse potential revenue streams, such as the sale of recycled materials, tipping fees, and government subsidies.

3. Economic Viability: Evaluate the economic viability by considering factors like the fluctuating prices of raw materials, the demand for recycled products, and the initial investment required for setting up recycling plants.

Case Studies

1. Comparative Analysis: Conduct a comparative analysis of successful and unsuccessful recycling plants. Focus on what differentiates financially sustainable plants from those that struggle.

2. Global Perspectives: Include case studies from various countries to understand how regional policies, market dynamics, and environmental regulations impact financial sustainability.

Financial Models and Tools

1. Cost-Benefit Analysis: Apply cost-benefit analysis to evaluate the financial sustainability of recycling plants. Consider long-term benefits versus short-term costs.

2. Life-Cycle Costing (LCC): Incorporate life-cycle costing to account for the total cost of ownership over the plant’s lifespan, including disposal costs and potential savings from recycling.

Policy and Regulatory Impact

1. Regulatory Frameworks: Examine how local, national, and international regulations impact the financial sustainability of C&D waste recycling plants.

2. Incentives and Penalties: Investigate the role of government incentives (e.g., tax breaks, subsidies) and penalties (e.g., landfill taxes) in promoting or hindering the financial sustainability of these plants.

Technological Innovations

Efficiency Improvements: Look into technological advancements that can improve the efficiency and reduce the operational costs of recycling plants.

Automation and AI: Explore the potential of automation and artificial intelligence in optimizing the sorting and recycling processes, thus impacting financial sustainability.

Market Dynamics

Supply Chain Integration: Study the integration of recycling plants within the construction industry’s supply chain and its impact on financial sustainability.

Market Demand: Analyze the market demand for recycled materials and how it influences the financial outcomes of recycling plants.

Environmental and Social Considerations

Sustainability Metrics: Include environmental and social sustainability metrics in your financial evaluation, as they can impact long-term financial sustainability.

Corporate Social Responsibility (CSR): Explore how CSR initiatives and sustainable practices can enhance the financial performance and reputation of recycling plants.

CHALLENGES AND OPPORTUNITIES

Economic Challenges: Identify the economic challenges faced by recycling plants, such as market volatility and competition with cheaper virgin materials.

Opportunities for Growth: Highlight emerging opportunities, like increasing demand for sustainable construction practices or new markets for recycled products.

SUMMARY OF FINDINGS

Construction and Demolition (C&D) waste, including materials such as concrete, bricks, tiles, timber, metals, and plastics, constitutes over 30% of global solid waste and poses significant environmental challenges. Effective management is crucial to mitigate its impact, with recycling offering a means to address resource scarcity and reduce pollution. Financially, recycling faces hurdles such as high costs, limited market demand, and logistical complexities.

This paper reviews the financial sustainability of construction and demolition (C&D) waste recycling plants, focusing on key factors like economic viability, revenue generation, and market dynamics. It highlights the environmental challenges posed by C&D waste and the importance of recycling in reducing resource depletion and pollution. Despite financial obstacles such as high operational costs and limited market demand, the study identifies significant revenue opportunities through the sale of recycled materials and government incentives. It emphasizes the potential of circular economy strategies to enhance financial sustainability by lowering raw material costs and improving resource efficiency. The review concludes that integrating technological innovation, supportive policies, and public awareness is crucial for advancing the financial performance and long-term viability of C&D waste recycling plants.

CONCLUSION

The findings of this study highlight the multifaceted nature of Construction and Demolition (C&D) waste management, emphasizing the environmental and economic implications of recycling. With C&D waste comprising over 30% of global solid waste, the urgency of addressing its environmental impact is evident. Recycling materials like concrete, bricks, tiles, timber, metals, and plastics not only mitigates resource depletion but also contributes to sustainable construction practices. However, the environmental benefits are tempered by significant financial challenges, including high operational costs, limited market demand for recycled products, and logistical hurdles. The study underscores that overcoming these challenges is critical to advancing the financial sustainability of recycling facilities.

       Financial sustainability in C&D waste recycling is influenced by various factors, such as operational costs, revenue streams, and economic viability. The study identifies potential revenue opportunities, including the sale of recycled materials, government incentives, and growing market demand for sustainable construction products. Case studies reveal that with adequate policy support and effective supply chain management, recycling plants can achieve profitability within a decade. However, the economic viability of recycling plants remains vulnerable to market volatility, competition with cheaper virgin materials, and the initial investment required. To enhance financial sustainability, the study advocates for stronger regulatory frameworks, technological advancements, and the integration of recycling into a circular economy framework.

In conclusion, the study emphasizes the need for a comprehensive approach to C&D waste recycling, one that balances environmental sustainability with financial viability. Strengthening policy support, increasing public awareness, and adopting innovative technologies are essential to overcoming the current challenges faced by recycling plants. The study also highlights the potential for growth in this sector, driven by emerging trends in sustainable construction and circular economy practices. Future research should focus on exploring these trends and leveraging data-driven insights to optimize the financial sustainability of C&D waste recycling plants.

RECOMMENDATION

The Study has the following recommendations for Future Research:

  1. Emerging Trends: Suggest areas for future research, such as the impact of circular economy practices on the financial sustainability of C&D waste recycling.
  2. Data-Driven Insights: Recommend the use of big data and predictive analytics to forecast financial trends and enhance decision-making in recycling plants.

REFERENCES

  1. Ahmed Osama Daoud, A. A. (2023). Analysis of factors affecting construction and demolition waste reduction in Egypt. Egypt: Tailor & Francis.
  2. Al-Raqeb, H., Ghaffar, S. H., M. J.-K., & Chougan, M. (2023). Understanding the challenges of construction demolition waste management towards circular construction: Kuwait Stakeholder’s perspective. Elsevier, 1-8.
  3. Al-Raqeb, H., Ghaffara, S. H., Al-Kheetan, M. J., & Chougan, M. (2023). Understanding the challenges of construction demolition waste management towards circular construction: Kuwait Stakeholder’s perspective. Elsevier, 1-8.
  4. Bansal, S., & Singh, S. (2014). A sustainable Approach towards the Construction and Demolition Waste. International Journal of Innovative Research of Science, Engineering and Technology, 9226- 9235.
  5. Castorina Silva Vieira, a. P. (2015). Use of recycled construction and demolition materials in geotechnical applications: A review. Porto: Elsevier.
  6. Dima W. Nazer, M. A. (2010). A Financial, Environmental and Social Evaluation of Domestic Water Management Options in the West Bank, Palestine. Palestine: Springer.
  7. Elshaboury, N., Al-Sakkaf, A., Mohammed Abdelkader, E., & Alfalah, G. (2022). Construction and Demolition Waste Management Research: A Science Mapping Analysis. International Journal of Environmental Research and Public Health, 19(8), 4496. https://doi.org/10.3390/ijerph19084496
  8. Ferronato, N. &. ( 2019). Waste mismanagement in developing countries: A review of global issues. . International Journal of Environmental Research and Public Health, 1060.
  9. G. Rodríguez, C. M. (2014). Assessment of C&DW plant management in Spain: in pursuit of sustainability and eco-efficiency. Granada : ELSEVIER.
  10. Ghiani, G. L. (2022). Circular Economy Strategies for Enhancing Financial Sustainability in Construction Waste Recycling. A Case Study Analysis. Waste Management, 124, 112-124.
  11. Gupta, S., & RK, M. (2018). The impact of C & D Waste on Indian Environment: A Critical Review. Civil Engineering Research Journal, 0057- 0063.
  12. Haya Hussain, a. E. (2023). Construction and Demolition Waste Management . India: IJREAM.
  13. Hölscher, K. &. (2021). Perspectives on urban transformation research: transformations in, of, and by cities. Urban Transformations, . 3(1), 1-14.
  14. Huanyu Wua, J. Z. (2019). A review of performance assessment methods for construction and demolition waste management. Australia: Elsevier.
  15. Hussin J, R. I. (2013). The way forward in sustainable construction: Issues and challenges. Int J Adv Appl Sci (IJAAS). 2(1): https://doi.org/10.11591/ijaas.v2i1.1321., 31–42.
  16. Huysman, S. D. (2017). Performance indicators for a circular economy?: a case study on post-industrial plastic waste. Resources Conservation And Recycling,. 46–54.
  17. Ibrahim, U. S., Ahmad, Dr. E., dulawat, S., Ubayi, S. S., ibrahim, I. A., Ibrahim, M. A., Garko, M. N., Ahmad, A., & Ishaq, I. Z. (2024). A Review on Coarse and Fine Recycled Aggregate Effect on the fresh and Hardened Properties of Self-compacting Concrete. International Journal in Engineering Sciences, 02(07), 35–47. https://doi.org/doi:10.5281/zenodo.12739633
  18. Juan A Ferriz-Papi a, E. W. (2022). A cost-effective recycled aggregates classification procedure for construction and demolition waste evaluation. Elsevier.
  19. K.R.A. Nunes, C. M. (2006). Evaluation of investments in recycling centres for construction and demolition wastes in Brazilian municipalities. Brazil: Elseviier.
  20. Lai Sheung Au, ,. S. (2018). System Dynamic Analysis of Impacts of Government Charges on Disposal of Construction and Demolition Waste: A Hong Kong Case Study. Hong Kong: Journal of MDPI.
  21. Leonidas Milios, A. E. (2010). Sustainability Impact Assessment of Increased Plastic Sustainability Impact Assessment of Increased Plastic Management in Sweden. sweden: MDPI.
  22. Navarro Ferronato, R. C. (2023). Construction and demolition waste recycling in developing cities:management and cost analysis . Springer.
  23. Ogulcan Yazgan, Y. O.-O. (2023). Construction and Demolition Waste Management in Urban Transformatio: A case study for performance Evaluation. Malaysia: Penerbit UTHM.
  24. Serdar Ulubeylia, A. K. (2017). Construction and demolition waste recycling plants revisited:management issues. TURKEY: ELSVIER.
  25. Shan-shan Chung, a. C. (2003). Evaluating sustainability in waste management: the case of construction and demolition, chemical and clinical wastes in Hong Kong. Hong Kong: Elsevier.
  26. Silvia Iodice, ,. E. (2021). Sustainability assessment of Construction and Demolition Waste management applied to an Italian case. Italian: Elsevier.
  27. Thakur, A., Misra, S., & Singh, A. (2022). FINANCIAL SUSTAINABILITY OF CONSTRUCTION AND DEMOLITION WASTE RECYCLING PLANTS. Proceedings of International Structural Engineering and Construction, 9(1). https://doi.org/10.14455/ISEC.2022.9(1).SUS-07
  28. Ubayi, S. S., Abubakar, Dr. B. S., Ahmad, Dr. E., Dulawat, S., Ibrahim, U. S., Ibrahim, I. A., & Garko, M. N. (2024). Shift from Traditional to Modern Building Concepts and Designs in Ringim Town: A Comparative Study of Aesthetics, Values, Functions and Durability. International Journal of Innovative Science and Research Technology (IJISRT), 2066–2074. https://doi.org/10.38124/ijisrt/IJISRT24JUN1536
  29. Ubayi, S. S., Ahmad, Dr. E., Dulawat, S., Abubakar, Dr. B. S., Garko, M. N., Ahmad, A., Ibrahim, U. S., & Ibrahim, I. A. (2024). A Review of the Impact of Jute Fiber Reinforcement on Mechanical Properties of Concrete. International Journal in Engineering Sciences, 02(07), 13–34. https://doi.org/doi:10.5281/zenodo.12670017
  30. Villalba, G. S. (2002). A proposal for quantifying the recyclability of materials. Resources, Conservation and Recycling. 39–53.
  31. Wang, J. T. (2004). A systems analysis tool for construction and demolition wastes management. Waste Manag. 24 (10), https://doi.org/10.1016/j.wasman.2004.07.010, 989–997.
  32. Yazdani, M. K. (2021). Improving construction and demolition waste collection service in an urban area using a simheuristic approach: A case study in Sydney. Australia. Journal of Cleaner Production, 280, 124138.
  33. Y?ld?z, S. K. (2020). Built environment design-social sustainability relation in urban renewal. Sustainable Cities and Society. 60, 102173.
  34. Zheng, L. W. ( 2017). Characterizing the generation and flows of construction and demolition waste in China. . Constr. Build. Mater, 136 https://doi.org/10.1016/j.conbuildmat. , 405–413

Reference

  1. Ahmed Osama Daoud, A. A. (2023). Analysis of factors affecting construction and demolition waste reduction in Egypt. Egypt: Tailor & Francis.
  2. Al-Raqeb, H., Ghaffar, S. H., M. J.-K., & Chougan, M. (2023). Understanding the challenges of construction demolition waste management towards circular construction: Kuwait Stakeholder’s perspective. Elsevier, 1-8.
  3. Al-Raqeb, H., Ghaffara, S. H., Al-Kheetan, M. J., & Chougan, M. (2023). Understanding the challenges of construction demolition waste management towards circular construction: Kuwait Stakeholder’s perspective. Elsevier, 1-8.
  4. Bansal, S., & Singh, S. (2014). A sustainable Approach towards the Construction and Demolition Waste. International Journal of Innovative Research of Science, Engineering and Technology, 9226- 9235.
  5. Castorina Silva Vieira, a. P. (2015). Use of recycled construction and demolition materials in geotechnical applications: A review. Porto: Elsevier.
  6. Dima W. Nazer, M. A. (2010). A Financial, Environmental and Social Evaluation of Domestic Water Management Options in the West Bank, Palestine. Palestine: Springer.
  7. Elshaboury, N., Al-Sakkaf, A., Mohammed Abdelkader, E., & Alfalah, G. (2022). Construction and Demolition Waste Management Research: A Science Mapping Analysis. International Journal of Environmental Research and Public Health, 19(8), 4496. https://doi.org/10.3390/ijerph19084496
  8. Ferronato, N. &. ( 2019). Waste mismanagement in developing countries: A review of global issues. . International Journal of Environmental Research and Public Health, 1060.
  9. G. Rodríguez, C. M. (2014). Assessment of C&DW plant management in Spain: in pursuit of sustainability and eco-efficiency. Granada : ELSEVIER.
  10. Ghiani, G. L. (2022). Circular Economy Strategies for Enhancing Financial Sustainability in Construction Waste Recycling. A Case Study Analysis. Waste Management, 124, 112-124.
  11. Gupta, S., & RK, M. (2018). The impact of C & D Waste on Indian Environment: A Critical Review. Civil Engineering Research Journal, 0057- 0063.
  12. Haya Hussain, a. E. (2023). Construction and Demolition Waste Management . India: IJREAM.
  13. Hölscher, K. &. (2021). Perspectives on urban transformation research: transformations in, of, and by cities. Urban Transformations, . 3(1), 1-14.
  14. Huanyu Wua, J. Z. (2019). A review of performance assessment methods for construction and demolition waste management. Australia: Elsevier.
  15. Hussin J, R. I. (2013). The way forward in sustainable construction: Issues and challenges. Int J Adv Appl Sci (IJAAS). 2(1): https://doi.org/10.11591/ijaas.v2i1.1321., 31–42.
  16. Huysman, S. D. (2017). Performance indicators for a circular economy?: a case study on post-industrial plastic waste. Resources Conservation And Recycling,. 46–54.
  17. Ibrahim, U. S., Ahmad, Dr. E., dulawat, S., Ubayi, S. S., ibrahim, I. A., Ibrahim, M. A., Garko, M. N., Ahmad, A., & Ishaq, I. Z. (2024). A Review on Coarse and Fine Recycled Aggregate Effect on the fresh and Hardened Properties of Self-compacting Concrete. International Journal in Engineering Sciences, 02(07), 35–47. https://doi.org/doi:10.5281/zenodo.12739633
  18. Juan A Ferriz-Papi a, E. W. (2022). A cost-effective recycled aggregates classification procedure for construction and demolition waste evaluation. Elsevier.
  19. K.R.A. Nunes, C. M. (2006). Evaluation of investments in recycling centres for construction and demolition wastes in Brazilian municipalities. Brazil: Elseviier.
  20. Lai Sheung Au, ,. S. (2018). System Dynamic Analysis of Impacts of Government Charges on Disposal of Construction and Demolition Waste: A Hong Kong Case Study. Hong Kong: Journal of MDPI.
  21. Leonidas Milios, A. E. (2010). Sustainability Impact Assessment of Increased Plastic Sustainability Impact Assessment of Increased Plastic Management in Sweden. sweden: MDPI.
  22. Navarro Ferronato, R. C. (2023). Construction and demolition waste recycling in developing cities:management and cost analysis . Springer.
  23. Ogulcan Yazgan, Y. O.-O. (2023). Construction and Demolition Waste Management in Urban Transformatio: A case study for performance Evaluation. Malaysia: Penerbit UTHM.
  24. Serdar Ulubeylia, A. K. (2017). Construction and demolition waste recycling plants revisited:management issues. TURKEY: ELSVIER.
  25. Shan-shan Chung, a. C. (2003). Evaluating sustainability in waste management: the case of construction and demolition, chemical and clinical wastes in Hong Kong. Hong Kong: Elsevier.
  26. Silvia Iodice, ,. E. (2021). Sustainability assessment of Construction and Demolition Waste management applied to an Italian case. Italian: Elsevier.
  27. Thakur, A., Misra, S., & Singh, A. (2022). FINANCIAL SUSTAINABILITY OF CONSTRUCTION AND DEMOLITION WASTE RECYCLING PLANTS. Proceedings of International Structural Engineering and Construction, 9(1). https://doi.org/10.14455/ISEC.2022.9(1).SUS-07
  28. Ubayi, S. S., Abubakar, Dr. B. S., Ahmad, Dr. E., Dulawat, S., Ibrahim, U. S., Ibrahim, I. A., & Garko, M. N. (2024). Shift from Traditional to Modern Building Concepts and Designs in Ringim Town: A Comparative Study of Aesthetics, Values, Functions and Durability. International Journal of Innovative Science and Research Technology (IJISRT), 2066–2074. https://doi.org/10.38124/ijisrt/IJISRT24JUN1536
  29. Ubayi, S. S., Ahmad, Dr. E., Dulawat, S., Abubakar, Dr. B. S., Garko, M. N., Ahmad, A., Ibrahim, U. S., & Ibrahim, I. A. (2024). A Review of the Impact of Jute Fiber Reinforcement on Mechanical Properties of Concrete. International Journal in Engineering Sciences, 02(07), 13–34. https://doi.org/doi:10.5281/zenodo.12670017
  30. Villalba, G. S. (2002). A proposal for quantifying the recyclability of materials. Resources, Conservation and Recycling. 39–53.
  31. Wang, J. T. (2004). A systems analysis tool for construction and demolition wastes management. Waste Manag. 24 (10), https://doi.org/10.1016/j.wasman.2004.07.010, 989–997.
  32. Yazdani, M. K. (2021). Improving construction and demolition waste collection service in an urban area using a simheuristic approach: A case study in Sydney. Australia. Journal of Cleaner Production, 280, 124138.
  33. Y?ld?z, S. K. (2020). Built environment design-social sustainability relation in urban renewal. Sustainable Cities and Society. 60, 102173.
  34. Zheng, L. W. ( 2017). Characterizing the generation and flows of construction and demolition waste in China. . Constr. Build. Mater, 136 https://doi.org/10.1016/j.conbuildmat. , 405–413

Photo
Idris Zakariyya Ishaq
Corresponding author

Department of Civil (Structural Engineering), Mewar University, Chittorgarh, Rajasthan India

Photo
Dr. Esar Ahmad
Co-author

Department of Civil (Structural Engineering), Mewar University, Chittorgarh, Rajasthan India

Photo
Shashivendra Dulawat
Co-author

Department of Civil (Structural Engineering), Mewar University, Chittorgarh, Rajasthan India

Photo
Dr. Bashir Sabo Abubakar
Co-author

Provost, Federal college of Education (Technical) Bichi, Kano State, Nigeria

Photo
Salihu Sarki ubayi
Co-author

Department of Civil (Structural Engineering), Mewar University, Chittorgarh, Rajasthan India

Photo
Abba Bashir
Co-author

Department of Civil (Structural Engineering), Mewar University, Chittorgarh, Rajasthan India

Photo
Umar Shehu Ibrahim
Co-author

Department of Civil (Structural Engineering), Mewar University, Chittorgarh, Rajasthan India

Photo
Mustapha Nuhu Garko
Co-author

Department of Civil (Structural Engineering), Mewar University, Chittorgarh, Rajasthan India

Photo
Muhammad Auwal Ibrahim
Co-author

Department of Civil (Structural Engineering), Mewar University, Chittorgarh, Rajasthan India

Idris Zakariyya Ishaq, Dr. Esar Ahmad, Shashivendra Dulawat, Dr. Bashir Sabo Abubakar, Salihu Sarki Ubayi, Abba Bashir, Muhammad Auwal Ibrahim, Umar Shehu Ibrahim, Mustapha Nuhu Garko, Evaluating The Financial Sustainability of Construction And Demolition Waste Recycling Plants: A Review, Int. J. in Engi. Sci., 2024, Vol 1, Issue 3, 1-17. https://doi.org/10.5281/zenodo.13341163

More related articles
Object Detection Using Yolo And Tensor Flow...
R. Goutham Sai Kalyan, M. Chinnarao, T. Naga Pravallika, B. Srini...
A Review of the Impact of Jute Fiber Reinforcement...
Salihu Sarki Ubayi , Dr Esar Ahmad , Dr. Bashir Sabo Abubakrar, S...
A Review on Coarse and Fine Recycled Aggregates Ef...
Umar Shehu Ibrahim, Dr. Esar Ahmad, Shashivendra Dulawat, Salihu ...
A Review of the Impact of Jute Fiber Reinforcement on Mechanical Properties of C...
Salihu Sarki Ubayi , Dr Esar Ahmad , Dr. Bashir Sabo Abubakrar, Shashivendra Dulawat, Mustapha Nuhu ...
Object Detection Using Yolo And Tensor Flow...
R. Goutham Sai Kalyan, M. Chinnarao, T. Naga Pravallika, B. Srinivas, ...
Related Articles
Object Detection Using Yolo And Tensor Flow...
R. Goutham Sai Kalyan, M. Chinnarao, T. Naga Pravallika, B. Srinivas, ...
A Review on Coarse and Fine Recycled Aggregates Effect on the Fresh and Hardened...
Umar Shehu Ibrahim, Dr. Esar Ahmad, Shashivendra Dulawat, Salihu Sarki Ubayi, Ibrahim Abdullahi Ibra...
A Stock Price Prediction Model Based On Investor Sentiment And Optimized Deep Le...
R. Sai Venkat, Konda Rishika, Anumula Shivatmika, Ramu Kuchipudi, Dr. T. Satyanarayana Murthy, Ramak...
Object Detection Using Yolo And Tensor Flow...
R. Goutham Sai Kalyan, M. Chinnarao, T. Naga Pravallika, B. Srinivas, ...
More related articles
Object Detection Using Yolo And Tensor Flow...
R. Goutham Sai Kalyan, M. Chinnarao, T. Naga Pravallika, B. Srinivas, ...
A Review of the Impact of Jute Fiber Reinforcement on Mechanical Properties of C...
Salihu Sarki Ubayi , Dr Esar Ahmad , Dr. Bashir Sabo Abubakrar, Shashivendra Dulawat, Mustapha Nuhu ...
A Review on Coarse and Fine Recycled Aggregates Effect on the Fresh and Hardened...
Umar Shehu Ibrahim, Dr. Esar Ahmad, Shashivendra Dulawat, Salihu Sarki Ubayi, Ibrahim Abdullahi Ibra...
Object Detection Using Yolo And Tensor Flow...
R. Goutham Sai Kalyan, M. Chinnarao, T. Naga Pravallika, B. Srinivas, ...
A Review of the Impact of Jute Fiber Reinforcement on Mechanical Properties of C...
Salihu Sarki Ubayi , Dr Esar Ahmad , Dr. Bashir Sabo Abubakrar, Shashivendra Dulawat, Mustapha Nuhu ...
A Review on Coarse and Fine Recycled Aggregates Effect on the Fresh and Hardened...
Umar Shehu Ibrahim, Dr. Esar Ahmad, Shashivendra Dulawat, Salihu Sarki Ubayi, Ibrahim Abdullahi Ibra...