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Author: Zhenhua Wei Publisher: ISBN: Category : Languages : en Pages : 150
Book Description
Ordinary portland cement (OPC) has been used as the primary binding material in concrete for construction of buildings and other infrastructure over the last century due to its low-cost and the widespread geographical abundance of its raw materials. The manufacture of OPC accounts for approximately 3% of primary energy use and 9% of anthropogenic CO2 emissions globally. Such energy consumption and CO2 release is mainly attributed to the calcination and clinkering of raw materials (i.e., limestone and clay) in the cement kiln at high temperatures. Therefore, there is great need to reduce the CO2 footprint of cement, and secure alternative solutions for cementation as required for building and infrastructure construction. On the other hand, space conditioning consumes nearly 20% of annual energy consumption in the United States, which is still increasing with the increasing demand for thermal comfort in the context of climate change. The embedment of phase change materials (PCMs) in concrete is an effective means to improve its thermal inertia for building envelope applications, and can thus improve the energy efficiency of buildings. However, the viability of employing PCMs to enhance thermal performance of concrete depends on the stability and durability of PCMs in the highly caustic cementitious environment, and the durability of the PCM-added concrete. To address these limitations on sustainability and energy efficiency of current cement-based building materials, this dissertation mainly examines: [TM] PCM survivability during fabrication of PCM-mortar composites with respect to damage and/or rupture of the PCM microcapsules that may occur during mechanical mixing, as well as chemical durability of PCM within cementitious matrices, and the potential interactions between the PCM and the pore-fluid that result in enthalpy alteration, [TM] Cementitious matrix durability, with emphasis on assessing how dosage of PCMs alters water absorption, drying shrinkage, and restrained shrinkage cracking behaviors of cementitious composites containing PCMs, and [TM] The feasibility of developing sustainable building material through clinkering-free cementation by fly ash carbonation, with emphasis on the effects of CO2 concentration and processing temperature on the progress of carbonation reaction, the development of microstructure, and the strength evolution of the material. The results of research on PCM embedded cementitious composites show that a reduction of around 25% in the phase change enthalpy is observed, irrespective of PCM dosage and aging. Such reduction in enthalpy is mainly caused by chemical interactions with dissolved sulfate ions. Examination of the influence of PCM additions on water absorption and drying shrinkage of PCM-mortar composites reveals that PCM microcapsules reduce the rate and extent of water sorption due to their non-sorptive nature and diluting effect. PCM inclusions do not influence the drying shrinkage of cementitious composites due to their inability to restrain the shrinkage of the cement paste. Assessments of free and restrained shrinkage, elastic modulus, and tensile strength also show that the addition of PCMs enhances the cracking resistance of cement paste because PCMs as soft inclusions offer crack blunting and deflection, and improved stress relaxation. In an effort to synergize the utilization of fly ash and CO2 in fly ash, the study shows that Ca-rich fly ash paste can readily react with dilute concentrations of CO2 in moist environments to produce cemented solids with sufficient strength (35 MPa) for use in structural construction. Detailed results from thermodynamic modeling, XRD analyses, and SEM observations suggest that fly ash carbonation results in the formation of reaction products including calcite, hydrous silica, and C-S-H, which collectively bond proximate particles into a cemented solid.
Author: Zhenhua Wei Publisher: ISBN: Category : Languages : en Pages : 150
Book Description
Ordinary portland cement (OPC) has been used as the primary binding material in concrete for construction of buildings and other infrastructure over the last century due to its low-cost and the widespread geographical abundance of its raw materials. The manufacture of OPC accounts for approximately 3% of primary energy use and 9% of anthropogenic CO2 emissions globally. Such energy consumption and CO2 release is mainly attributed to the calcination and clinkering of raw materials (i.e., limestone and clay) in the cement kiln at high temperatures. Therefore, there is great need to reduce the CO2 footprint of cement, and secure alternative solutions for cementation as required for building and infrastructure construction. On the other hand, space conditioning consumes nearly 20% of annual energy consumption in the United States, which is still increasing with the increasing demand for thermal comfort in the context of climate change. The embedment of phase change materials (PCMs) in concrete is an effective means to improve its thermal inertia for building envelope applications, and can thus improve the energy efficiency of buildings. However, the viability of employing PCMs to enhance thermal performance of concrete depends on the stability and durability of PCMs in the highly caustic cementitious environment, and the durability of the PCM-added concrete. To address these limitations on sustainability and energy efficiency of current cement-based building materials, this dissertation mainly examines: [TM] PCM survivability during fabrication of PCM-mortar composites with respect to damage and/or rupture of the PCM microcapsules that may occur during mechanical mixing, as well as chemical durability of PCM within cementitious matrices, and the potential interactions between the PCM and the pore-fluid that result in enthalpy alteration, [TM] Cementitious matrix durability, with emphasis on assessing how dosage of PCMs alters water absorption, drying shrinkage, and restrained shrinkage cracking behaviors of cementitious composites containing PCMs, and [TM] The feasibility of developing sustainable building material through clinkering-free cementation by fly ash carbonation, with emphasis on the effects of CO2 concentration and processing temperature on the progress of carbonation reaction, the development of microstructure, and the strength evolution of the material. The results of research on PCM embedded cementitious composites show that a reduction of around 25% in the phase change enthalpy is observed, irrespective of PCM dosage and aging. Such reduction in enthalpy is mainly caused by chemical interactions with dissolved sulfate ions. Examination of the influence of PCM additions on water absorption and drying shrinkage of PCM-mortar composites reveals that PCM microcapsules reduce the rate and extent of water sorption due to their non-sorptive nature and diluting effect. PCM inclusions do not influence the drying shrinkage of cementitious composites due to their inability to restrain the shrinkage of the cement paste. Assessments of free and restrained shrinkage, elastic modulus, and tensile strength also show that the addition of PCMs enhances the cracking resistance of cement paste because PCMs as soft inclusions offer crack blunting and deflection, and improved stress relaxation. In an effort to synergize the utilization of fly ash and CO2 in fly ash, the study shows that Ca-rich fly ash paste can readily react with dilute concentrations of CO2 in moist environments to produce cemented solids with sufficient strength (35 MPa) for use in structural construction. Detailed results from thermodynamic modeling, XRD analyses, and SEM observations suggest that fly ash carbonation results in the formation of reaction products including calcite, hydrous silica, and C-S-H, which collectively bond proximate particles into a cemented solid.
Author: Cesare Sangiorgi Publisher: MDPI ISBN: 3038973521 Category : Electronic books Languages : en Pages : 213
Book Description
This book is a printed edition of the Special Issue "Recent Advances in Smart Materials for the Built Environment" that was published in Materials
Author: Breeann Sharma Publisher: ISBN: Category : Building materials Languages : en Pages : 90
Book Description
Manufacture of building materials requires significant energy, and as demand for these materials continues to increase, the energy requirement will as well. Offsetting this energy use will require increased focus on sustainable building materials. Further, the energy used in building, particularly in heating and air conditioning, accounts for 40 percent of a buildings energy use. Increasing the efficiency of building materials will reduce energy usage over the life time of the building. Current methods for maintaining the interior environment can be highly inefficient depending on the building materials selected. Materials such as concrete have low thermal efficiency and have a low heat capacity meaning it provides little insulation. Use of phase change materials (PCM) provides the opportunity to increase environmental efficiency of buildings by using the inherent latent heat storage as well as the increased heat capacity. Incorporating PCM into concrete via lightweight aggregates (LWA) by direct addition is seen as a viable option for increasing the thermal storage capabilities of concrete, thereby increasing building energy efficiency. As PCM change phase from solid to liquid, heat is absorbed from the surroundings, decreasing the demand on the air conditioning systems on a hot day or vice versa on a cold day. Further these materials provide an additional insulating capacity above the value of plain concrete. When the temperature drops outside the PCM turns back into a solid and releases the energy stored from the day. PCM is a hydrophobic material and causes reductions in compressive strength when incorporated directly into concrete, as shown in previous studies. A proposed method for mitigating this detrimental effect, while still incorporating PCM into concrete is to encapsulate the PCM in aggregate. This technique would, in theory, allow for the use of phase change materials directly in concrete, increasing the thermal efficiency of buildings, while negating the negative effect on compressive strength of the material.
Author: Ali Akbar Ramezanianpour Publisher: Springer Science & Business Media ISBN: 3642367216 Category : Science Languages : en Pages : 345
Book Description
The aim of this book is to present the latest findings in the properties and application of Supplementary Cementing Materials and blended cements currently used in the world in concrete. Sustainability is an important issue all over the world. Carbon dioxide emission has been a serious problem in the world due to the greenhouse effect. Today many countries agreed to reduce the emission of CO2. Many phases of cement and concrete technology can affect sustainability. Cement and concrete industry is responsible for the production of 7% carbon dioxide of the total world CO2 emission. The use of supplementary cementing materials (SCM), design of concrete mixtures with optimum content of cement and enhancement of concrete durability are the main issues towards sustainability in concrete industry.
Author: Ashraf Ashour Publisher: Elsevier ISBN: 0443156735 Category : Technology & Engineering Languages : en Pages : 749
Book Description
Sustainable Concrete Materials and Structures focuses on recent research progress and innovations in this important field of research. All aspects of the technical routes to sustainable concrete and structures are discussed in detail. These include recent findings on sustainable concrete production and structural design and construction. Low-carbon cement, sustainable concrete mix design, durability, and structural applications are discussed in detail. Emphasis is placed on how to bring some of the innovations in concrete technology closer to market. Information on techno-economic analysis, economy of scale, and the supply chain of sustainable concrete is also addressed. The book will be an essential reference resource for academic and industrial researchers working in civil engineering, material science, chemical engineering, and the development and manufacture of construction materials. - Provides a comprehensive collection of technical reviews on the latest advancements in sustainable concrete materials and structures - Presents state-of-the-art research on preparation, production, processing, and implementation techniques for sustainable concrete materials and structures - Features techno-economic analysis for each technology discussed - Covers lifecycle assessment, the Circular Economy and end of life of concrete structures - Includes industry case studies on implementation
Author: Sayed Hemeda Publisher: BoD – Books on Demand ISBN: 178985749X Category : Technology & Engineering Languages : en Pages : 282
Book Description
This book sheds light on recent advances in sustainable construction and building materials with special emphasis on the characterization of natural and composite hydraulic mortars, advanced concrete technology, green building materials, and application of nanotechnology to the improvement of the design of building materials. The book covers in detail the characterization of natural hydraulic lime mortars, a decade of research on self-healing concrete, biocomposite cement binding process and performance, development of sustainable building materials from agro-industrial wastes, applications of sugarcane biomass ash for developing sustainable construction materials, oil-contaminated sand: sources, properties, remediation, and engineering applications, oil shale ash addition effect in concrete to freezing/thawing, connection node design and performance optimization of girders, functionally graded concrete structures, cumulative tensile damage and consolidation effects on fracture properties of sandstone, key performance criteria influencing the selection of construction methods used for the fabrication of building components in the Middle East, fly ash as a resource material for the construction industry, degradation monitoring systems for a building information modeling maintenance approach, durability of composite-modified asphalt mixtures based on inherent and improved performance, and bitumen and its modifiers.
Author: Pierre-Claude Aïtcin Publisher: CRC Press ISBN: 1482266695 Category : Technology & Engineering Languages : en Pages : 328
Book Description
Production of Portland cement is responsible for about seven percent of the world's greenhouse gas emissions. The pressure to make the production of concrete more sustainable, or "greener", is considerable and increasing. This requires a wholesale shift in processes, materials and methods in the concrete industry. Pure Portland cement will nee
Author: Jorge de Brito Publisher: Woodhead Publishing ISBN: 0128208953 Category : Technology & Engineering Languages : en Pages : 810
Book Description
Waste and By-Products in Cement-Based Materials: Innovative Sustainable Materials for a Circular Economy covers various recycled materials, by-products and wastes that are suitable for the manufacture of materials within the spectrum of so-called cement-based materials (CBM). Sections cover wastes for replacement of aggregates in CBM, focus on the application of wastes for the replacement of clinker and mineral additions in the manufacture of binders, discuss the optimization process surrounding the manufacture of recycled concrete and mortars, multi-recycling, advanced radiological studies, optimization of self-compacting concrete, rheology properties, corrosion prevention, and more. Final sections includes a review of real-scale applications that have been made in recent years of cement-based materials in roads, railway superstructures, buildings and civil works, among others, as well as a proposal of new regulations to promote the use of waste in the manufacture of CBM. Favors the institution of the circular economy in the construction industry by eliminating the barriers that currently prevent industrial waste from being valorized by its inclusion in CBM design Features an in-depth exploration of the strengths and weaknesses of new raw materials and their application to CBMs Features real-scale applications that have been made in recent years of cement-based materials in roads, railway superstructures, buildings and civil works, among others Presents current, state-of-the-art, and future-prospects for the use of industrial waste in CBMs
Author: José Aguiar Publisher: Trans Tech Publications Ltd ISBN: 3038267368 Category : Technology & Engineering Languages : en Pages : 580
Book Description
The special topic volume includes selected and extended papers form the Luso-Brazilian Conference of Sustainable Construction Materials. This bookcontains extended papers selected and reviewed by the Scientific Committee, in areas such as Materials and Energy, Materials and Residues, Natural Materials and Materials and Repair.
Author: Benjamin Alexander Young Publisher: ISBN: Category : Languages : en Pages : 163
Book Description
This thesis aims to investigate design strategies for concrete construction materials containing microencapsulated phase change materials (PCMs) for energy- efficient buildings and sustainable infrastructure. First, numerical studies based on rigorous finite element simulations were carried out to predict the effective elastic moduli and thermal deformation coefficient of composites consisting of spherical core-shell microcapsules in a continuous matrix, and to identify effective medium approximations (EMAs) capable of accurately estimating these effective properties. Next, experiments studying the thermal behavior of small- scale test cells were conducted to evaluate the performance of microencapsulated PCM-composite building envelope materials. Scaling analysis was used to show how these small-scale test cells, conveniently placed in an environmental chamber, could represent the thermal behavior of time- and space-intensive full-scale outdoor test structures. Furthermore, a thermal model of a room with a PCM- composite envelope was used to examine the energy and cost savings potential of PCM-composite walls in the presence of an active indoor temperature control scheme. A model predictive control (MPC) algorithm that could preemptively account for melting and freezing of the PCM was developed. However, it did not significantly increase the energy and cost savings compared with a traditional proportional control scheme. Finally, temperature evolutions within microencapsulated PCM-composite concrete pavement sections were studied numerically. The inclusion of microencapsulated PCM within the pavement section was found to reduce early-age temperature rise and corresponding spatial temperature gradients induced by cement hydration, thereby reducing the risk of early-age thermal cracking. Overall, the results of this thesis will be useful in the design of composite concrete containing microencapsulated phase change materials for sustainable infrastructure projects, including energy-efficient building envelopes and road pavements with enhanced lifetime.
Author: Zhenhua Wei
Author: Zhenhua Wei
Author: Cesare Sangiorgi
Author: Breeann Sharma
Author: Ali Akbar Ramezanianpour
Author: Ashraf Ashour
Author: Sayed Hemeda
Author: Pierre-Claude Aïtcin
Author: Jorge de Brito
Author: José Aguiar
Author: Benjamin Alexander Young