Mixing Of Raw Materials Research Articles

Analysis Magnetic Properties and Corrosion Resistance of Hybrid Bonded Magnet BaFe<sub>12</sub>O<sub>19</sub>-NdFeB

Permanent Magnets made in the form of hybrid bonded BaFe12O19 / NdFeB and with binder of Poli Vynil Alcohol (PVA) as much as 3% of the total mass in each sample. The weight ratio hybride system BaFe12O19 : NdFeB is 0 % BaFe12O19 : 100 % NdFeB ; 50% BaFe12O19 : 50 % NdFeB and 70% BaFe12O19 : 30 % NdFeB. The material preparation process was begun from mixing of raw materials using HEM for 15 minutes, then added 3% wt. of PVA. The mixed powder was formed a pellet using a hydraulic press with a force of 4 tons for 1 minute, then heated with an vacuum oven at a temperature of 110 ° C for 1 hour and the last step was magnetization using impulse magnetizer. The characterization of pellet sample was done namely measurement of bulk density, flux magnetic and hysteresis loop using VSM and then measurement of corrosion resistance of hybride bonded magnet. The characterization results show that bulk density value of sample hybride 50% BaFe12O19 – 50 % NdFeB is more larger than sample hybride 70% BaFe12O19 – 30 % NdFeB , and The highest coercivity and remanence values ​​of 3900 Oe and 2500 Gauss respectively were achieved in samples with a composition of 50% Ba-ferrite - 50% NdFeB. The hybride bonded magnet Ba-ferrite/NdFeB has more corrosion resistance than bonded magnet 100 % NdFeB.

Influence of the technological properties of cement-sand mortar on the quality of 3D printed products

The results of the influence of cement-sand mortar mobility on quality of hardened composites, made by 3D concrete printing (3DCP), are presented. Four formulations of cement-sand mortar mixes with mobility classes Pk 1, Pk 2, Pk 3, Pk 4 which corresponds to immersion depth of the reference cone of 3.3 cm, 6.5 cm, 8.7 cm, 12.0 cm, respectively, were prepared for testing. It has been established that regulatory framework regulating 3DCP test methods not sufficiently developed and requires further improvement. It was revealed 3D printing of cement-sand mortar mixes with mobility classes Pk 2-Pk 4 on researched 3D printer is possible, however, products have defects and damages. Mortar mobility has a significant impact on structure kinetics and geometric parameters deviation. The lower mobility class is, the higher structure kinetics of raw material mix is, which is due to the early formation of the crystallization structure of hardened composite. Cement-sand mortar with class mobility Pk 2 accepted for further research in the development of adapted raw mixes for 3DCP.

Production and Performance Evaluation of Noble Fire Extinguishing Foam Suspensions Using Locally Available and Environmentally Friendly Natural Mineral Raw Materials

The main goal of this research is the fabrication of halogen free, environmentally friendly fire-extinguishing powders using local mineral raw materials and the development of technological processes for producing highly efficient fire-extinguishing foam-suspensions on the basis of the produced powders. Fire-extinguishing powders are made by mechanical treatment and mixing of raw materials: zeolite, clay shale, perlite and ammophos. The process does not need introduction of expensive, halogen-containing, hydrophobizators and ensures the cost-effective production of fire-extinguishing powders. The obtained fire-extinguishing powders are characterized by high performance properties, high fire-extinguishing capacity and coefficient of atomic oxygen recombination. Thus, they are characterized both by homogeneous and heterogeneous inhibition of combustion processes. The efficiency of the produced powders is not inferior to that of standard powders of common production. In addition, in contrast to their traditional analogs they are halogen free, environmentally friendly and cheaper (1.2-2 times cheaper). The obtained powders, unlike the ones of conventional production, have good compatibility with water and foam. Our foam-suspensions are prepared just by mechanical mixing of fire-extinguishing powders with water and surface-active substances – foamers. The process does not require chemical treatment of materials. Thus, the developed technology is simple and cost-effective. The foam-suspensions produced on the basis of the obtained powders have higher heat capacity, permeability, wetting effect like water and foam and unlike them, they allow for homogeneous as well as heterogeneous inhibition of the burning process. Thus, the so produced foam-suspensions will have higher extinguishing effect than water, foams or powders, taken separately. Based on the above, it can be suggested that the produced powders can be used for extinguishing all types of fires, including large-scale ones in a combination with water and foams.
 Chemical Engineering Research Bulletin 21(2019) 58-64

Prediction of physical properties of thermosetting resin by using machine learning and structural formulas of raw materials

AbstractThermosetting resins are one of the most widely used functional materials in industrial applications. Although some of the physical properties of thermosetting resins are controlled by changing the functional groups of the raw materials or adjusting their mixing ratios, it was conventionally challenging to construct machine learning (ML) models, which include both mixing ratio and chemical information such as functional groups. To overcome this problem, we propose a machine learning approach based on extended circular fingerprint (ECFP) in this study. First, we predicted the classification of raw materials by the random forest, where ECFP was used as the explanatory variable. Then, we aggregated ECFP for each classification predicted by the random forest. After that, we constructed the prediction model by using the aggregated ECFP, feature quantities of reaction intermediates, and curing conditions of resin as explanatory variables. As a result, the model was able to predict in high accuracy (R^2 = 0.8), for example, the elastic modulus of thermosetting resins. Furthermore, we also show the result of verification of prediction accuracy in first step, such as using the one-hot-encording. Therefore, we confirmed that the properties of thermosetting resins could be predicted using mixed raw materials by the proposed method.

ОПТИМИЗАЦИЯ СОСТАВА СЫРЬЕВОЙ СМЕСИ СЕРЕБРЯНСКОГО ЦЕМЕНТНОГО ЗАВОДА

now a top trend of technical development in the cement industry of Russia, is optimization of all technological repartitions of production. Obtaining the quality portlandtsement is multiple-factor process. It is influenced not only by the physical and chemical transformations of raw materials occurring during the firing of cement clinker, but also what will be the composition of the raw mixture and whether this mixture is prepared qualitatively. Work consists in a research and selection of an optimum compounding of raw mix, with the purpose to receive cement with high rates of quality. This direction will allow: first, to expand a source of raw materials, to process raw materials which go to dumps because in it is mute a large amount of quartz and impurity connections contains; secondly, to make small reconstruction of the line of preparation of raw mix. At the moment, the plant works on mixed mixtures of aluminosilicate raw materials, i.e. two types of aluminosilicate raw materials which are previously mixed in certain ratios therefore it affects on the accuracy of dispensing of components are used. Accuracy of dispensing of modern batchers, a component ± (1 … 2) %, is often insufficient. In this regard, the new option of optimum composition of mix is offered and investigated. This option of a "clean" mixing of components, will allow to improve process of mixing of initial raw materials, to operate process of drawing up proportions of mixes in a supply line of materials. And also it will allow to eliminate long-term deviations, guaranteeing the solution of problems at the earliest stage of their emergence. Receiving a qualitative ready-made product, reduction of costs for energy resources and cost efficiency of the proposed solution is result of this work

Optimization of pilot-scale in-vessel composting process for various agricultural wastes on elevated temperature by using Taguchi technique and compost quality assessment

Rapid treatment processing for agricultural waste is of the utmost importance with the boom in the agriculture sector of China. This research aimed to examine the influence and optimize the applied temperature and allowed processing time in accelerating the degradation and mineralization rates of the in-vessel composting of agricultural wastes. Under the umbrella of Taguchi technique, total 09 experiments were conducted with three levels of temperature (55°C, 65°C, 75°C) and time (15h, 18h, 22h) in a pilot-scale composter equipped with control systems for temperature, aeration, agitation, and humidity for the composting of poultry manure (PM), vegetable waste (VW), and rice straw (RS) mixed at ratio 5.5:3.5:1 respectively. Results showed that among all treatments, the combination of temperature 65°C and time 18h was an optimal treatment based on S/N ratio and experimental data analysis. Material Loss Analysis of this most stabilized compost showed final masses of mixed raw material, dry matter, moisture contents, TN, and TP were reduced by 78 %, 50 %, 93 %, 23 %, and 41 % of initial masses respectively. Elimination rates of volatile fatty acid and NH+4-N were observed at 98 % and 79 %, respectively. Little higher pH (8.3) showed slight alkane nature of the optimal compost having 26wt.% moisture content, 9.9±0.5wt. % of dm total nutrients (N+K2O+P2O5), and acceptable limits of heavy metals. All these physiochemical characteristics were within limits of the Chinese Standards of Organic Fertilizer (2012). Overall medium size particle distribution was observed under the macroscopic analysis.

“Material works” in sacred space: ritual attributes in the context of symbolic information (archetypes, images and symbols)

The object of this research is ritual attributes applied in different ceremonies, associated with the spirits Ichchi and celestial deities of Aya, which possess a superior modeling and communicative function. The article describes the ritual sacred items that were not used in everyday life, such as the sacrificial spoon of the Aya-shaman, kumis ladle, fortunetelling spoon, and spatula of the potter. Interdisciplinary approach allowed applying a historical-cognitive method of research, which views an item as a narrative text and a creative tool for transforming the sacred space. The novelty consists in the fact that despite the sufficient examination of correlation between a myth and a ritual, semiotic aspects of functionality of one or another item, organization of the sacred space, etc. of the Sakha people, these ritual attributes did not become a subject of semiotic study and determination of their structural-functional role within the mythical-ritual space of the Sakha people. The conclusions is made that these ritual attributes have a mediating function that establishes a communicative link between the Aya-shaman and transcendental space; in all ritual acts they are involved in modeling a stable life environment. It is revealed that mixing of raw materials (kumis, clay) was similar to the act of creation of Man and Nature, and the Aya-shaman performed the function of a demiurge. The author believes that all these functions could underlie a single ritual attribute – the sacrificial spoon, which later became a prototype of the shamanic drum mallet.

Thermodynamic data for cement clinkering

The proportions of cement clinker phases produced by the pyro-processing of a raw-material mix are often predicted through the Bogue equations, established in the 1930s; however, the Bogue approach is limited in its applicability. This presents a challenge as the cement industry is seeking innovative and more environmentally friendly cement clinker formulations and production processes. These often go beyond the limitations of the Bogue equations and more flexible approaches are required. Modern thermodynamic calculations allow this flexibility but rely on databases not freely available and often specialised for other applications. The title paper reviews the thermodynamic data for stoichiometric clinker phases and presents a new dataset. The dataset is validated and its application demonstrated by case studies. Electronic CSV files containing the data which can be parsed for use with existing Gibbs energy minimisation solvers/software is distributed with this article as supplementary material.

Sago pulp and rice husk as an alternative material for the cultivation of oyster mushroom (Pleurotus ostreatus)

During this time, the wood powder is one of the primary raw materials in making mushroom cultivation media. Alternative other raw materials need to be developed to diversify the oyster mushroom cultivation media. Sago pulp waste and rice husk are chosen as the planting medium for oyster mushroom cultivation because they contain cellulose, hemicellulose, and lignin needed by the fungus. This study aims to determine the composition of sago pulp and rice husk as the best growing media for the growth and development of white oyster mushrooms. The method used in this study is mixing raw materials (the cultivation media), sterilizing raw materials, inoculating, maintaining, and harvesting. There are five treatments in mixing raw materials, namely the use of 100% sago pulp waste (P1); 75% of sago pulp and 25% of husk rice powder (P2); 50% of sago pulp and 50% of husk rice powder (P3); 25% sago waste and 75% husk rice powder (P4); and 100% rice husk (P5) as a control. The use of 50% sago pulp and 50% husk rice powder (P3) and 25% sago pulp and 75% husk rice powder (P4) produces the right cultivation media. Whereby using both of these mediums, it takes 42 days from the growing media inoculated mushrooms until the oyster mushrooms are ready to be harvested. However, if the use of baglog P3 as a growth medium will get better yields because of the wet weight (60 grams) and the number of mushroom fruit bodies (16 fruits) that harvested is higher.

RANCANG BANGUN MESIN PELET BIOMASSA TERINTEGRASI DENGAN PENDEKATAN DIAGRAM FAST

The purpose of this research is to support and encourage the development of sustainable palm oil, reduce the environmental impact caused by the rehabilitation of oil palm plants that are not well managed by the managers of oil palm plantations and produce technological.Therefore, in-depth analysis is needed related to the innovation of biomass pellet printing machine (biopellet) technology using the diagram function Function Analysis and System Technique (FAST). Analysis is done by determining the critical functions that must be present in an integrated biomass pellet machine (biopellet) on the performance of a machine that can produce biomass pellets (biopellet) and is moveable. The results of the study using the FAST approach produce engine design that has the main function in a biopellet machine that is moveable by considering the critical functions such as the cutting function of waste palm stalks, enumeration functions, raw material mixing functions, pellet printing functions and skeleton holder functions that can integrate all functions engine by considering the moveable nature of the engine. It is hoped that this research can be developed even better starting from the quality of the cutting edge of the blade on the machine and the printing quality of the biopellet.

Preparation and characterization of bakelite bonded magnet NdFeB used for electric generator

The permanent magnets based on NdFeB is well known as rare earth alloy magnets made from neodymium, iron and boron elements and has tetragonal crystalline structure Nd2Fe14B which has high coercivity, large energy product (app 50 MGOe) and curie temperature about 312 °C. In this paper will be discussed the preparation of bakelite bonded magnet NdFeB and characterization, also the purpose of this research is to make bonded magnet NdFeB using 3 % bakelite and know the extent to which can be applied in making a small electric generator. The bonded magnet NdFeB was made by mixing a magnetic powder NdFeB with a polymer as binder. The composition of the sample consisted of 97 wt. % of NdFeB powder and 3 wt.% of bakelite. The mixed raw materials were then pressed to form a disc with pressure about 40 MPa at temperature about 160 °C for 20 minutes. It was obtained a disc with size 40 x 18 x 6 mm. The disc samples were magnetized by using impulse magnetizer at 1500 Volt DC, then the samples were measured magnetic properties by using Gauss meter and Permeagraph. The measurements result show that, the bakelite bonded magnet NdFeB has Magnetic Flux = 1100 Gauss, Remanence Br = 5.20 kGauss, Coercivity Hc = 6.14 kOe and Energy product (BH) max = 4.78 MGOe. The bonded magnet NdFeB was applied to the prototype small generator with single rotor and single stator. The results of performance test of generator indicate that it is achieved output power of generator about 9.98 Watt at a maximum speed about 500 rpm.

Predicting macronutrients and energy content of snack products using FT-NIR analysis and chemometric techniques

Nowadays, the consumption of snack products is permanently increasing. Because of the growing trend of snack consumption, it is more and more difficult to guarantee the quality and safety of the products. Near infrared spectroscopy (NIRS) method, combined with chemometric techniques provide outstanding solutions, due to its rapidity and simple sample preparation. The objective of this study was to investigate the possibilities of using NIRS to predict fat, protein, carbohydrate, sugar and salt content of all in all 155 commercially available snack products from 25 countries. The prediction models were performed using partial least squares regression (PLSR) with different spectral pre-processing methods. Different pre-processing methods proved to be the best to predict the five macronutrients, however, the final models showed good accuracy |R2/Q2 > 0.94/0.82|. The energy content of the samples was calculated from the measured parameters and interval PLS regression was accomplished to improve prediction parameters. The methods developed are suitable for analyzing snacks made from single or mixed raw materials.

A facile strategy for recovering spent LiFePO4 and LiMn2O4 cathode materials to produce high performance LiMnxFe1-xPO4/C cathode materials

To successfully recycle spent LiFePO4 and LiMn2O4 batteries and simultaneously produce high performances nano-LiMnxFe1-xPO4/C powders, a mechanical activation-assisted method was effectively applied in the recycling process. The technique consists of the separation and purification of spent cathode materials, high-energy mechanical mixing of raw materials and a commonly used heat treatment processes. The structural and morphological characterization results indicate that nano-sized LiMnxFe1-xPO4/C composites with uniform amorphous carbon coatings were successfully synthesized from spent LiFePO4 and LiMn2O4 batteries. The electrochemical performance testing results show that the recovered nano-LiMnxFe1-xPO4/C cathodes possess promising Li-ion storage properties. LiMn0.5Fe0.5PO4/C displays high capacities of 143.2, 138.1, and 127.6 mAh g−1 at 0.1, 1, and 2C rates, respectively. The obtained cathodes also show outstanding cycling stabilities of 98.47% and 97.58% for LiMn0.5Fe0.5PO4/C and LiMn0.8Fe0.2PO4/C after 100 cycles, respectively. This work indicates that recycling spent LiFePO4 and LiMn2O4 to produce high-performance LiMnxFe1-xPO4/C is a promising strategy for recycling spent LiFePO4 and LiMn2O4 based lithium ion batteries (LIBs) in an efficient and environmentally friendly manner.

Non-Catalytic Co-pyrolysis of Empty Fruit Bunch of Palm and Solid Tire Waste Into Upgrade Bio-oil

Depletion of petroleum and environmental problem have led to look for alternative fuel sources. In many ways, biomass is a potential renewable source. Among the many forms of biomass, empty fruit bunch (EFB) of palm oil is very attractive feedstock due to its abundance, low price and non-competitiveness with the food chain. EFB can be converted into bio-oil by pyrolysis process, but this product can not be used directly as a transportation fuel, as it needs to undergo a process of an upgrade to bio-oil. Co-pyrolysis is a biomass pyrolysis process with solid material that has a high hydrogen index at atmospheric pressure. One of the materials that have a higher hydrogen index than biomass is polymer, such as solid tire waste. The objectives of this research are to study the treatment effects on EFB, the influence ratio of solid tire waste with EFB, and temperature of the yield and composition of the product. EFB that had been treated was mixed with the waste tire, wihh a weight ratio of (100: 0, 75:25, 50: 50.25: 75 and 0: 100) between EFB and waste tire. The mixed raw material was put into the co-pyrolysis reactor and heated at 400 – 600 o C with nitrogen gas flowing for 45 minutes. The results showed that the treatment of EFB as the raw material of pyrolysis could increase the yield of bio-oil and improve the quality of bio-oil. With the addition of 75% waste tire in the co-pyrolysis raw material, the composition of hydrocarbons in bio-oil became 59.55% with a bio-oil heating value of 33.1 MJ/kg.

To the Question of Structure Formation of Dispersed Systems in Cement Technology

In the this publication, readers will find the results of the analytical and experimental research into the physical and chemical processes in the consecutive formation of structures at the major technological stages of the present-day production of portland cement. Dispersed systems of raw mixtures, which in different methods of production are formed at the stage of grinding, mixing and homogenization of raw materials, belong to different classification groups. In wet and combined methods is produced cement sludge - aqueous dispersed system, which belongs to the 2nd group: two-phase systems such as solid dispersed phase - liquid dispersion medium. In the dry method dispersed system is formed, which belongs to the 3rd group: three-phase systems such as solid dispersed phase - water-liquid and air-gas dispersion medium. The structural-mechanical and rheological properties of the coagulation structure of cement slurries, wich differ in the main raw material components, are shown. The study of deformation processes of aqueous dispersed systems showed that the nature of the development of deformations - rapid elastic ε₀’, slow elastic ε₂’ and plastic ε₁’τ sludge samples belong to different structural - mechanical types. At the same time differences in quantitative values and a ratio of the specified types of deformation are noted. Readers will also find the particularities of the phase changes in the process of the crystallization structure formation at baking to maximum temperature 1450°С.

Modeling the horizontal movement of bulk material in the system “conveyor – rotary mixer”

In this work, we consider methods for analytical construction of the profile of rotor blades mixer, as well as mathematical modeling of their work on moving and mixing bulk material on a conveyor to increase process efficiency mixing raw materials and optimizing its operating costs. In addition to increasing the effectiveness of the mixing process and lower operating costs, the goal of implementation the proposed methods is the consciousness of production with the least possible errors that would meet modern technical requirements and be adapted to consumer tasks. In this regard, the aim of this work was to determine rational parameters and geometric characteristics of the profile of the rotor mixer blades contributing to improving the quality of mixing the metallurgical charge transported on a conveyor belt. To achieve the goal by modeling, which is a key method of the fourth concept industrial revolution, using the developed mathematical model analyzed the movement of a particle of material along a conveyor belt with its subsequent interaction with the blades of the working body of the rotary mixer.

Influence of NaX (X=Cl, Br, I) additive on phase composition, thermostability and high infrared performances of γ-La2S3 transparent ceramics

A simple method to synthesize Na+-doped La2S3 powder with only γ phase was developed where NaX (X = Cl, Br, I) served as sodium source. In initial molar ratio Na/La ≥ 0.8 of the mixed raw materials, γ-La2S3:Na+ tended to reach a constant ratio Na/La = 0.2 and could be represented as Na0.5La2.5S4, which exhibited enough high-temperature stability available for sintering. A modified process was designed to prepare γ-La2S3 ceramics with NaCl additive. The microstructure, typical grain boundary composition, photoluminescence and IR performance of as-sintered γ-La2S3 ceramics were investigated in details. The optical transparency with mean transmittance 61.3% in 8–14 μm and maximum 64.03% at 13.1 μm was achieved for pellet with Na:La = 0.2 and 1.0 wt% NaCl nanocrystals. NaCl was proved to play multiple roles in governing phase composition, enhancing stability, optimizing microstructure, improving IR properties and affecting luminescence of γ-La2S3 ceramics. The mechanisms of action of NaCl additive are proposed by combining the defects reaction, ionic radius and the diffusion behavior of related ions with the cation-deficient structure of γ-La2S3.

Establishment and verification of a model for the movement of pulverized sweet sorghum stalks in a rotary drum bioreactor by discrete element method

The mixing of raw materials in a rotary drum bioreactor is important for advanced solid-state fermentation technology. However, the shape, size, and other properties of pulverized sweet sorghum stalk particles are more complicated than those of the spherical particles. In this study, a soft rod-shaped discrete particle model was established and verified to simulate the mixing behavior of sweet sorghum stalk particles in a rotary drum bioreactor. We were inspired by the particle shape and established a rod-shaped particle model by investigating the influence of the shape (length–diameter ratio) and size (diameter) on the particle packing (stack height and bed porosity). We used orthogonal simulations and extremum difference analysis to determine the main factors, optimum level, and groups of other parameters. Based on calibrated parameters, twelve sets of simulations of radial mixing in the drum were performed, and the results were compared with experiments conducted under identical operating conditions. The average relative error between the simulation and the experiment was 10.95%, which indicates that they agreed well and that the simulation could predict the mixing process well.

Life cycle assessment of melange yarns from the manufacturer perspective

Different proportions of colored fibers are able to spin into melange yarns with different colors and textures. With the advantages of energy saving, water saving, and emissions reduction in their production, melange yarns become more and more popular in manufacturers. However, the environmental performance of melange yarns with different colors has not been well investigated, which makes fashion designers unable to consider environmental performance when determining the color scheme of their design works. This study focuses on evaluating the environmental impacts of melange yarns spun from different colored fibers and identifying the environmental hotspots, in order to seek opportunities for improvement from the manufacturer’s perspective. A cradle-to-gate life cycle assessment (LCA) of melange yarns was performed, where the investigated phases include raw material acquisition, transportation, dyeing, mixing, and spinning. The functional unit is 1 ton of the finished melange yarns. The primary data of nine melange yarns spun from monochrome fibers, i.e., white, brown, blue, purple, green, yellow, red, black, and gray, were collected by on-site investigation in a large manufacturer in China. The environmental impacts of the nine melange yarns were evaluated using the ReCiPe method. The environmental impacts were indicated by 15 impact categories including climate change, terrestrial acidification, freshwater eutrophication, marine eutrophication, ozone depletion, water depletion, metal depletion, fossil depletion, freshwater ecotoxicity, marine ecotoxicity, terrestrial ecotoxicity, human ecotoxicity, ionizing radiation, particulate matter formation, and photochemical oxidant formation. The results obtained from the LCA demonstrated that spinning phase and dyeing phase in the production of melange yarns are main contributors to environmental impacts. The electricity and tap water consumptions are found to be the dominant contributors to most of impact categories, except terrestrial ecotoxicity, metal depletion, and ionizing radiation, whereas these environmental impacts are related to the wastewater treatment process. The recycled water is beneficial to reduce environmental burdens and can bring over 30% environmental benefits to the category of freshwater ecotoxicity. Melange yarns spun from white fibers have the least impact on the environment because of the lower electricity and water consumptions. The potential hotspots identified are tap water use, reactive dyestuffs and auxiliaries use in the dyeing phase, and the electricity consumption in spinning phase. This work points out the future direction for the textile industry to improve the environmental performance.

Influence of Pseudowollastonite on the Performance of Low Calcium Amorphous Hydraulic Binders.

A systematic investigation of the influence of pseudowollastonite on the performance of a new family of low calcium hydraulic binders is described. Samples of the new low calcium binder were produced by an innovative process consisting of heating and homogenizing the mix of raw materials (limestone, sand, and fuel cracking catalyst) at a constant temperature followed by the rapid cooling of the mixture itself. Different maximum temperatures, close to the melting temperature of the mix, were tested, and materials with CaO/SiO2 (C/S) ratios of 0.9, 1.1, and 1.25 were produced into the form of the amorphous phase with small percentages of pseudowollastonite. Compressive strength results were determined at 7, 28, and 90 days of hydration, and the hydrated phases were analyzed using isothermal calorimetry, X-ray diffraction (XRD) analysis, thermogravimetry analysis (TGA), scanning electron microscopy (SEM), and differential scanning calorimetry (DSC). The present work is focused on the influence of the percentage of the pseudowollastonite phase on the binder compressive strength performance.