Analysis of sustainable concrete obtained from the by-products of an industrial process and recycled aggregates from construction and demolition waste

warming. In response to the extreme climate changes and the lack of primary resources that social-economic systems are The excessive exploitation of natural resources for construction is producing an extreme impact on air pollution and global experiencing all over the world, international and local governments are supporting the development of the culture of warming. In response to the extreme climate changes and the lack of primary resources that social-economic systems are sustainable manufacturing, following the principles of the circular economy. In this context, the present study supports the experiencing all over the world, international and local governments are supporting the development of the culture of research on the design of sustainable and cross-industry value chains. This paper investigates the characteristics of sustainable sustainable manufacturing, following the principles of the circular economy. In this context, the present study supports the concrete obtained from industrial waste and recycled aggregates from construction and demolition waste. The industrial waste research on the design of sustainable and cross-industry value chains. This paper investigates the characteristics of sustainable adopted in this study is the by-product of an industrial production process. The aim was to investigate the characteristics of concrete obtained from industrial waste and recycled aggregates from construction and demolition waste. The industrial waste such a by-product as a recycled additive for sustainable concrete and to assess its eco-compatible safety performance. The adopted in this study is the by-product of an industrial production process. The aim was to investigate the characteristics of results suggest that the by-products adopted in this research provide an interesting alternative to the use of primary resources, such a by-product as a recycled additive for sustainable concrete and to assess its eco-compatible safety performance. The e.g. the fine sand, in the concrete mixture. However, the optimal amount of by-products depends on the characteristics of the results suggest that the by-products adopted in this research provide an interesting alternative to the use of primary resources, waste material in the mixture. The eco-compatibility test was performed to investigate the leaching behavior of the proposed e.g. the fine sand, in the concrete mixture. However, the optimal amount of by-products depends on the characteristics of the sustainable concrete. The present research promotes the adoption of a cross-industry and circular approach towards waste material in the mixture. The eco-compatibility test was performed to investigate the leaching behavior of the proposed sustainability, showing that the use of industrial waste to produce sustainable concrete allows benefits for all the stakeholders sustainable concrete. The present research promotes the adoption of a cross-industry and circular approach towards involved in the value chain and for society. sustainability, showing that the use of industrial waste to produce sustainable concrete allows benefits for all the stakeholders involved in the value chain and for society.