EM - Escola de Minas
URI permanente desta comunidadehttp://www.hml.repositorio.ufop.br/handle/123456789/6
Notícias
A Escola de Minas de Ouro Preto foi fundada pelo cientista Claude Henri Gorceix e inaugurada em 12 de outubro de 1876.
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Resultados da Pesquisa
Item Use of steel slag and LAS-based modifying admixture in obtaining highly eco-efficient precast concrete products.(2023) Martins, Ana Carolina Pereira; Carvalho, José Maria Franco de; Duarte, Matheus do Nascimento; Pedroti, Leonardo Gonçalves; Ribeiro, José Carlos Lopes; Peixoto, Ricardo André FiorottiThis paper presents a study on improving the eco-efficiency of no-slump concrete for precast elements using Basic Oxygen Furnace Slag (BOFS). Recycled BOFS powders and aggregates have been produced to obtain mixtures with better particle size distribution and improved packing density based on a particle packing method. A comprehensive experimental investigation was carried out on mixtures with different cement contents (5%, 10%, and 15% vol.) and compaction energy levels (6, 10, and 20 blows in a sand rammer). A modifying admixture based on Linear Alkyl Benzene Sodium Sulfonate (LAS) has also been evaluated as a workability and cohesiveness enhancer for steel slag concretes. In addition, concrete eco-efficiency was evaluated by measuring the binder intensity (bi) and waste consumption. The highest compaction energy provided packing densities ranging from 0.78 to 0.80, and BOFS aggregates led to better mechanical performances. The BOFS concrete containing 15% cement obtained the best strength (52.1 MPa) and bi value (7.0 kg/m3 /MPa), with a waste consumption of 2356.57 kg/m3 . The mixture with the lowest cement consumption (5% - 121.56 kg/m3 ) and the highest consumption of waste (2637.82 kg/m3 ) reached 16 MPa, delivering a bi of 7.6 kg/m3 /MPa.Item Steel slags in cement-based composites : an ultimate review on characterization, applications and performance.(2021) Martins, Ana Carolina Pereira; Carvalho, José Maria Franco de; Costa, Laís Cristina Barbosa; Andrade, Humberto Dias; Melo, Tainá Varela de; Ribeiro, José Carlos Lopes; Pedroti, Leonardo Gonçalves; Peixoto, Ricardo André FiorottiSteel slags are by-products generated in high volumes in the steel industry. Their main constituents are calcium, silicon, ferric, aluminum, and magnesium oxides. Larnite, alite, brownmillerite, and ferrite are also found. The presence of expansive compounds cause concern when used in cement-based compos- ites; however, mitigating routes have been proposed. Activation techniques improve the binding proper- ties of steel slag powder, potentiating its use as a supplementary cementitious material (SCM). As an aggregate, steel slag presents good morphological and mechanical properties. Promising mechanical and durability performances in cement-based composites encourage further research to promote the use of steel slag.Item Low environmental impact cement produced entirely from Industrial and mining waste.(2019) Carvalho, José Maria Franco de; Campos, Paula Anunciação Matias; Silva, Keoma Defáveri do Carmo e; Silva, Guilherme Jorge Brigolini; Pedroti, Leonardo Gonçalves; Peixoto, Ricardo André FiorottiProper disposal of industrial waste, the need to conserve nonrenewable resources, and high CO2 emissions are the major environmental issues at the present time. A significant portion of emissions from portland cement production is related to the energy required to maintain the clinker kiln at a temperature of approximately 1,450°C, which is necessary for alite formation. The alternative belite phase, however, requires lower temperatures for its formation (below 1,250°C). Although belite is less reactive than alite, it is equally efficient at higher hydration times. Thus, a belitic cement produced entirely with industrial waste (grits from the pulp and paper industry, steel slag, and quartzite mining tailings) is presented in this research. The raw meal was proportioned based on Bogue calculation and the firing was performed in a muffle furnace at a temperature of 1,250°C. A reference belitic cement was produced with limestone and clay under the same conditions. The results showed that both cements presented high belite contents and expected technological performance. The reference belitic cement revealed a higher reactivity, whereas the waste cement proved to be a technically feasible low-impact alternative.