construction waste

Concrete, as one of the main materials in the construction industry, plays a vital role in the sustainability, safety, and welfare of urban spaces. This is because concrete has a direct impact on bearing gravitational and lateral loads, and improving the quality of concrete can prevent the premature destruction of buildings. Additionally, it can reduce the volume of construction waste and create a sustainable urban environment. However, numerous factors affect the compressive strength of concrete, and failing to identify these factors can lead to premature building destruction and adverse outcomes during natural disasters. A proper understanding of these factors is essential for enhancing concrete quality and ensuring the optimal performance of structures. Accordingly, the aim of this article is to analyze the factors influencing the quality and strength of concrete to improve the sustainability, safety, and welfare of urban spaces and to protect the urban environment. In this article, to achieve the research objectives, in addition to using a machine learning model based on the Extreme Gradient Boosting algorithm, metaheuristic algorithms have been employed to create an accurate predictive model.

Nowadays considering the growth of the population and increasing the need for housing, construction activities have been booming more remarkably than the past. So, the volume of construction waste has increased which has caused many environmental problems. These derbies have potation to reuse in construction activities. Recycling is one of the best ways to manage this debris. Because it reduces the volume of waste. It also confirms to reusing, and it reduces the need to extract and uses natural resources. Considering the importance of this, this waste can be used as replacement of aggregates in concrete. In this study, the effect of different percentages of replacement of construction and demolition waste as coarse aggregate on mechanical properties of concrete has been investigated, and the effect of using these debris on compressive strength, tensile strength and flexural strength concrete was studied. The percentages of replacement are 0%, 10%, 20%, 30%, and 50%, and the water to cement ratio is 0.49. Tests were done for two curing time 7 and 28 days. Also, in order to analysing the results, statistical analysis of one-way ANOVA was carried out. The results show that with increasing the replacement rate, compressive strength, tensile strength and flexural strength are decreased, but these decreases aren’t significant

The present study was conducted to investigate the reduction factors of construction waste in folding logistic projects in Sirjan city. The statistical population of this research includes contractors and engineers and all factors related to construction. The sample consists of 86 people who were selected by simple random sampling method. The instrument used in this research is a researcher-made questionnaire and a 9-factor questionnaire fuzzy ahp. Five hypotheses are the modernization of the construction industry. Proper design and consistent adaptation to changing needs. Proper storage and transportation methods and the use of recyclable materials, which proved these assumptions. An expert questionnaire has been reviewed to prioritize these hypotheses, and the criteria for each of their hypotheses have been identified. The results showed that storing and transportation of first and second rank and proper design and updating of the construction industry and the use of recycled materials are respectively from the highest to the lowest priority, and according to the criteria according to the type of order and fit with the climate conditions, the lack of coordination in the design and Implementing and using industrial methods and reuse of recyclable materials are more important than other components of their group. Once priorities are identified, management can make better decisions and plans to reduce construction waste, as well as information from well-known experts who use the system as
A decision support system.

Nowadays, mass production of construction waste is one of the most important environmental issues. Construction industry consumes a large amount of materials and resources, especially in developing countries. Inefficient usage of bulk materials results in production of construction waste. According to sustainable development guidelines, mass production of construction waste is one of the issues of focused concern. In Iran, there is no clear record or valid data about different aspects of construction waste production. Quantification of the construction waste production is one of the new concepts in waste management. Therefore, the aim of this research is to quantify construction waste production of bulk materials in residential buildings. The focus of this study is on rebar, concrete, brick, and cement waste produced in the buildings.The urban developers may utilize the results to regulate more detailed and precise rules to control the production of construction waste. The dependent variable of the study is the amount of waste produced for every type of material in percent. The independent variables of the study are location of residential buildings, type of contract, area of every story, and number of stories in every residential building. Furthermore, two frequent types of contracts for residential buildings cost-plus and lump-sum contracts are investigated. Obtained data is analyzed by SPSS software using linear regression, and then are verified and validated to extract the best and most convenient regressions. The criteria for validation and verification of the quantitative equations are derived from statistical references and the most recent and related studies. The result is four valid and verified quantitative models describing the amount of waste materials produced in terms of independent variables. Results show that choosing cost-plus contract leads to more construction waste production than lump-sum contract. The positive and negative effects of other dependent variables, such as location, number of stories, or area of each story are determined too.

With limited material resources and fragile environment, the need to recycle materials is inevitable. Waste from construction and demolition has good potential for recycling. These materials are usually abandoned or buried in the ground without being efficiently used. Retrieve them, while solving environmental problems will also be conservation for limited natural resources. Construction waste can be separated after crushing, screening, and grading and then can be used as aggregate in concrete construction. In the recycling industry, what will be remained after recycling old tires are rubber powder and steel wires. Therefore, the use of steel wire in the concrete in addition to solving environmental problems, improve the mechanical properties of concrete too.In this study the role of recycled steel fibers in concrete containing recycled aggregates have been investigated.Rates of replacement of this type of aggregate with coarse natural aggregate are: 0%, 50% and 100%. The amount of fibers used in the mix design is 0.5%of concrete volume. The results showed that the addition of steel fibers in concrete with recycled aggregate, low resistance can be recovered.