Ecological Assessment of Clay Brick Manufacturing in China Using Emergy Analysis

Zhang, Junxue; Srinivasan, Ravi; Peng, Changhai

doi:10.3390/buildings10110190

Cited by 18 publications

(9 citation statements)

References 57 publications

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“…The transformity value can be obtained from emergy databases and previous research or it can also be derived from the global baseline. Thus, transformity becomes a matter of the ecosystem components and a sort of property of energy simultaneously [52].…”

Section: Static Emergy Analysis Modelmentioning

confidence: 99%

Design of Rural Human Settlement Unit with the Integration of Production-Living-Ecology of China Based on Dynamic Emergy Analysis

et al. 2023

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It is of great theoretical and practical significance to optimize and improve the design of rural human settlement units through system ecology analysis based on emergy evaluation indices. From the perspective of system ecology, the rural living environment system is multivariate and complicated, with strong correlations and obscure boundaries between levels. Therefore, the definition of a rural human settlement unit in China is proposed in this research and can be divided into three scales: the microcosmic scale, mesoscale, and macroscopic scale. This research adopted a new method for the design of rural human settlement units by adopting emergy as a common dimension in order to solve the problem of dimensionality disunity between resource environment elements and society economy elements. Through the establishment of the static emergy analysis model and dynamic emergy prediction model, qualitative and quantitative analysis approaches of the rural human settlement unit were combined. According to the design orientations of industry-invigorative, environment-friendly, and ecology-balanced, corresponding with production-living-ecology integration, emergy evaluation indices including the emergy self-sufficiency ratio, emergy investment ratio, net emergy yield ratio, environmental load ratio, and emergy sustainable indices were calculated and predicted by means of system dynamics simulation. The dynamic emergy prediction results showed that the emergy self-sufficiency ratio and emergy sustainable indices basically presented a decreasing tendency, from 0.34 to 0.15 and from 0.76 to 0.57, respectively, with the passage of time; the values of the emergy investment ratio, net emergy yield ratio, and environmental load ratio basically presented an increasing tendency, from 2.13 to 2.78, from 1.66 to 2.12, and from 2.23 to 3.61, respectively, with the passage of time. In practice, the evaluation method based on the emergy analysis of the technical strategies and spatial arrangements of the rural human settlement unit can provide data support for designing standards, planning guidelines, and creating constructional instructions for the rural living environment of China.

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Section: Static Emergy Analysis Modelmentioning

confidence: 99%

Design of Rural Human Settlement Unit with the Integration of Production-Living-Ecology of China Based on Dynamic Emergy Analysis

et al. 2023

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“…Sustainable emergy evaluation of building material systems is a popular research direction that includes material production processes as well as labor and transportation inputs. As building materials are one of the main components of the building system, research in this direction is valuable [22][23][24][25][26][27]. The combination of Building Information Modeling (BIM) technology and building systems has brought more accurate research results to sustainable architecture, and the fully visualized results provide designers and engineers with a more intuitive sense, improving the ecological level of the entire building system [28,29].…”

Section: Introductionmentioning

confidence: 99%

The Sustainability Study and Exploration in the Building Commercial Complex System Based on Life Cycle Assessment (LCA)–Emergy–Carbon Emission Analysis

et al. 2023

Self Cite

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This paper focuses on the sustainable exploration of building systems, which combines ecological concepts and low-carbon designs for a comprehensive sustainability assessment investigation. The study employed the Life Cycle Assessment (LCA)-Emergy and Life Cycle Assessment (LCA)-Carbon emission methods to discuss a range of topics, including the main contributing factors, sustainability index verification, sensitivity analysis, and potential improvement measures. From an ecological sustainability perspective, the results indicate that the building operation stage plays a critical role, accounting for approximately 45% of the entire emergy in the building commercial complex. The sustainable index (ESI) is 0.354, which is below the standard of 1. Moreover, the building operation stage also significantly contributes to carbon emissions, particularly in the 50th anniversary of operation. Based on these findings, the study recommends two potential strategies to improve the ecological state and low-carbon design which involve the use of renewable energy and carbon sink improvement, respectively.

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“…This enormous amount of brick production brings rise to the discussion of natural clay resource shortage, where in India alone, 700-750 million tons of clay is consumed annually for brick manufacturing. Yet, clay is not only used in the construction industry, but also in other industries such as pharmaceutical membranes, filters, thermal insulators, and bioceramics [1] Therefore, to reduce clay usage and overcome clay depletion, alternative materials are studied to replace clay, and in some countries, such as China, the implementation of restrictions on clay consumption for brick manufacturing has already started [2]. Other than fertile soil depletion, landfill scarcity for residues from industries is also another environmental problem for a green world [3].…”

Section: Introductionmentioning

confidence: 99%

Manufacturing of Fired Clay Bricks for Internal Walls with Dolomite Residue as a Secondary Material

Kandymov,

Korpayev,

Durdyev

et al. 2023

Buildings

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Alternative materials need to be mapped, characterized, and valued in order to reduce clay usage. A study was conducted on the utilization of waste dolomite material from a mirror manufacturing factory in the production of bricks where the factory disposes 2500 tons of dolomite waste annually. Dolomite residue was mixed with clay raw material in various mass ratios of 90/10, 87.5/12.5, 85/15, and 82.5/17.5 wt%, extruded with proper moisture content, dried at 110 °C, and fired at 1000 °C and 1100 °C. The addition of dolomite resulted in an efflorescence on the surface of the bricks while also providing thermal insulation advantages and higher fire resistance. The addition of dolomite allowed for an increase in firing temperature to 1100 °C, which was initially not possible due to the melting characteristics of the clay. Dolomite also decreased the density of the bricks, which is crucial in order to decrease the dead load in structures. The produced bricks are intended for internal wall applications because of the efflorescence on the surface of the bricks. Overall, the addition of dolomite improved thermal conductivity and density, and other characteristics also showed suitable results.

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Ecological Assessment of Clay Brick Manufacturing in China Using Emergy Analysis

Cited by 18 publications

References 57 publications

Design of Rural Human Settlement Unit with the Integration of Production-Living-Ecology of China Based on Dynamic Emergy Analysis

Design of Rural Human Settlement Unit with the Integration of Production-Living-Ecology of China Based on Dynamic Emergy Analysis

The Sustainability Study and Exploration in the Building Commercial Complex System Based on Life Cycle Assessment (LCA)–Emergy–Carbon Emission Analysis

Manufacturing of Fired Clay Bricks for Internal Walls with Dolomite Residue as a Secondary Material

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