Your search keyword '"MINERAL wool"' showing total 2,091 results

1. Blend Technology to Enable Lignophenolic Resins on Industrial Scale

Author

Bliem, Peter, Sailer-Kronlachner, Wilfried, van Herwijnen, Hendrikus W. G., da Silva, Lucas F. M., Series Editor, Ferreira, António J. M., Series Editor, Adams, Robert D., editor, Sato, Chiaki, editor, and Dilger, Klaus, editor

Published

2025

2. Methodological steps forward in toxicological in vitro screening of mineral wools in primary rat alveolar macrophages and normal rat mesothelial NRM2 cells.

Author

Ziemann, Christina, Schulz, Florian, Koch, Christoph, Solvang, Mette, and Bitsch, Annette

Subjects

*ALVEOLAR macrophages, *THERMAL insulation, *MINERAL wool, *CYTOTOXINS, *ACOUSTICAL materials

Abstract

Man-made vitreous fibers (MMVF) comprise diverse materials for thermal and acoustic insulation, including stone wool. Depending on dimension, durability, and dose, MMVF might induce adverse health effects. Therefore, early predictive in vitro (geno)toxicity screening of new MMVF is highly desired to ensure safety for exposed workers and consumers. Here, we investigated, as a starting point, critical in vitro screening determinants and pitfalls using primary rat alveolar macrophages (AM) and normal rat mesothelial cells (NRM2). A stone wool fiber (RIF56008) served as an exemplary MMVF (fibrous vs. ground to estimate impact of fiber shape) and long amosite (asbestos) as insoluble fiber reference. Materials were comprehensively characterized, and in vivo-relevant in vitro concentrations defined, based on different approaches (low to supposed overload: 0.5, 5 and 50 µg/cm2). After 4–48 h of incubation, certain readouts were analyzed and material uptake was investigated by light and fluorescence-coupled darkfield microscopy. DNA-strand break induction was not morphology-dependent and nearly absent in both cell types. However, NRM2 demonstrated material-, morphology- and concentration-dependent membrane damage, CINC-1 release, reduction in cell count, and induction of binucleated cells (asbestos > RIF56008 > RIF56008 ground). In contrast to NRM2, asbestos was nearly inactive in AM, with CINC-1 release solely induced by RIF56008. In conclusion, to define an MMVF-adapted, predictive in vitro (geno)toxicity screening tool, references, endpoints, and concentrations should be carefully chosen, based on in vivo relevance, and sensitivity and specificity of the chosen cell model. Next, further endpoints should be evaluated, ideally with validation by in vivo data regarding their predictivity. [ABSTRACT FROM AUTHOR]

Published

2024

3. High-temperature structural drivers immobilizing alkaline substances in red mud-derived mineral wool.

Author

Chen, Ziwei, Wei, Ying, Ji, Weiyi, Huang, Yujie, Liu, Lili, Zhang, Shipeng, and Poon, Chi Sun

Subjects

*THERMODYNAMICS, *VISCOUS flow, *ALUMINUM oxide, *MINERAL wool, *ACTIVATION energy

Abstract

Smelting and fiberization of red mud (RM) is an attractive approach for rapid recovery of metal resources, production of mineral wool, and immobilization of hazardous alkalis. However, an enormous challenge remains in understanding alkali immobilization behavior in mineral wool over a broad A/S (Al 2 O 3 to SiO 2 mass ratio) range. Here we addressed the challenge through molecular dynamics, thermodynamic and experimental analyses. Increasing A/S ratio caused an increasing degree of structural order and the remarkable micro-phase separation occurred at A/S > 0.9. The role of Na+ and Ca2+ changed from the network-modifying cations to the charge-compensating cations. Melt viscosity decreased and then increased significantly with an intensified temperature sensitivity, identified by the increasing viscous flow activation energy from 211.5 to 377.03 kJ/mol in the temperature region from 1500 to 1570 °C. The transformation of thermodynamic properties (real mixed/excess molar Gibbs free energies, and entropy increment) corresponded to the structural changes. Thermal, mechanical and leaching tests confirmed the negative effect of this structural transformation on alkali immobilization. The A/S ratios controlled below 0.9 were proposed for environmental benefits and product stability. The investigation of immobilization mechanism provides valuable information for tuning the vitrification chemistry and developing safe and green mineral wool from RM. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

4. Experimental study on mechanical and thermal insulation properties of a geopolymer‐based fireproof sandwich panel.

Author

Pei, Rui, Hua, Luqing, Zhao, Hu, Wang, Xin, Li, Shiyang, and Wu, Zhishen

Subjects

*THERMAL conductivity, *CORE materials, *THERMAL insulation, *THERMAL properties, *MINERAL wool, *SANDWICH construction (Materials), *FIRE resistant polymers

Abstract

This work created a fireproof sandwich structure in which the face sheets were made of expanded vermiculite and expanded perlite‐filled geopolymer composites and embedded basalt fiber mats and the core material was rock wool in designing the lightweight and cost‐effective fire‐resistant structure for steel bridges with excellent retardant and heat‐insulating performance. The effects of adding 5%, 10%, 15%, and 20% expanded vermiculite and expanded perlite to the geopolymer on mechanical properties and the thermal conductivity were investigated to obtain the optimized material mixtures for preparing the face‐sheets material of the sandwich panel. Then, the fireproof sandwich structures were fabricated and exposed to 800°C for 3 h to study the structural integrity, backfire side temperature, and mass loss ratio. The results indicated that adding 10 wt% expanded vermiculite and 10 wt% expanded perlite to the geopolymer achieved the retention of compressive strength of 66.5% after being exposed to 800°C, and the geopolymer mixtures showed a low thermal conductivity of 0.1942 W/(mK). The TOPSIS evaluation analysis reveals that the proposed fireproof sandwich panel had the highest integrated performance considering the structural weight, insulation properties, and cost. The findings of this work may provide some insights into fireproof and insulating applications in bridge engineering. [ABSTRACT FROM AUTHOR]

Published

2024

5. Preparation and Performance Study of CaCl 2 Composite Adsorbent Based on Rock Wool Board Suitable for Continuous Heat Storage/Release of Trombe Wall.

Author

Xiao, Yutong, Wei, Siyu, Yang, Yuanyi, Wang, Chunhao, and Peng, Shanbi

Subjects

*ENERGY conservation in buildings, *HEAT storage, *MINERAL wool, *CALCIUM chloride, *SOLAR technology

Abstract

As a passive solar design technology, the Trombe wall can improve buildings' energy efficiency and thermal comfort. However, the traditional Trombe wall heating efficiency is low and cannot meet the needs of continuous night heating of the building. To solve these problems, a new type of sheet-like composite adsorbent is proposed in this study, prepared from calcium chloride supported by a rock wool board, a high-porosity building material. The high adaptability of rock wool board to the building wall makes it possible for the composite adsorbent to be directly applied to the Trombe wall. The results show that the macroporous structure of the rock wool board provides a wealth of space for loading hydrated salts. The smaller the density and thickness, the more calcium chloride the rock wool board can carry, speeding up the absorption/deportation process. The rock wool slab-based calcium chloride composite adsorbent has a maximum adsorption capacity of 51% and a heat storage density of about 838 J/g. Achieving the desorbed balance within 8 h and applying it to the Trombe wall is expected to attain continuous heating of buildings and has significant potential in building energy conservation. [ABSTRACT FROM AUTHOR]

Published

2024

6. Optimierung des Trittschallschutzes von Holzbalkendecken in Gründerzeithäusern – Teil 2: Deckenaufbau und Flankenübertragung.

Author

Neusser, Maximilian and Wegerer, Paul

Subjects

*SOUNDPROOFING, *ARCHITECTURAL acoustics, *MINERAL wool, *CEILINGS, *POLYURETHANES

Abstract

Optimization of impact sound insulation of wooden beam ceilings in Wilhelminian style houses, Part 2: Ceiling construction and flanking transmission The research deals with the influence of various parameters in the ceiling structure, such as cavity damping, screed thickness, impact sound insulation, fill and suspended ceilings, on the standard impact sound level of typical Wilhelminian style wooden beam ceilings. The measurements show that a thicker screed, softer impact sound insulation and a heavier fill significantly improve the impact sound level. Binding the fill with polyurethane instead of cement shows a significant improvement in the frequency range from 100 to 500 Hz. While cavity damping with mineral wool only contributes to a limited reduction in the standard impact sound level, decoupling the fill on an elastic intermediate layer delivers significant improvements. The measurements also show that the thickness of the paneling and the type of hangers in suspended ceilings have a significant impact on impact sound insulation. The investigations into flank impact sound transmission make it clear that flank transmission must be taken into account when planning higher requirement levels. Especially in the frequency range between 250 Hz and 800 Hz, the sound transmission of flanking components can play a significant role in the overall transmission. [ABSTRACT FROM AUTHOR]

Published

2024

7. Test methods for determination of shear properties of sandwich panels.

Author

Silwal, Shekhar, Mela, Kristo, and Ma, Zhongcheng

Subjects

*MODULUS of rigidity, *TRANSVERSE strength (Structural engineering), *SHEAR strength, *TEST methods, *MINERAL wool, *SANDWICH construction (Materials), *WALL panels

Abstract

This paper presents analysis and comparison of test methods for determining transverse shear strength and shear modulus of steel-faced sandwich panels commonly used in construction. The test methods are taken from the governing European standard EN 14509:2013. Two-point loading and four-point loading test methods as well as a full-scale test method are examined. Based on extensive experimental work on sandwich panels with varying core thickness, comprising mineral wool (MW) and polyisocyanurate (PIR) and encompassing both roof and wall panels, this study provides details of the test setup for the four-point loading and vacuum box methods with which a pure shear failure is obtained. Such details are missing from EN 14509. This paper highlights that the two-point loading method fails to consistently produce shear failure, especially in thicker panels, indicating it does not accurately measure transverse shear strength. The results of the experiments conducted in this study indicate that the four-point loading and full-scale test methods provide consistent shear failure for thicker panels while yielding greater transverse shear strength than the two-point loading test in general. [ABSTRACT FROM AUTHOR]

Published

2024

8. Material and assembling imperfections to discoloration in the ETICS insulation system plaster.

Author

Krause, Paweł, Olechowska, Marcelina, and Kosobucki, Łukasz

Subjects

MINERAL wool, AESTHETICS, CONSTRUCTION costs, THERMAL properties, PLASTER

Abstract

Copyright of Materiały Budowlane is the property of Wydawnictwo SIGMA-NOT and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

9. Requirements of the Vapour Barrier in Wood-Frame Walls.

Author

Hansen, Søren Schaldemann, Thomsen, Martin Aagaard, Morelli, Martin, and Rasmussen, Torben Valdbjørn

Subjects

VAPOR barriers, INSULATING materials, EXTERIOR walls, AERODYNAMIC heating, MINERAL wool

Abstract

This paper examines the water-vapour diffusion resistance (Z-value) of vapour versus wind barriers by determining their Z-value ratio in exterior wood-frame walls thermally insulated with six different materials to prevent mould growth. Using WUFI Pro, the water-vapour diffusion resistance requirements were determined for thermal insulation using mineral wool and biogenic materials: wood fibre, straw, flax, grass, and hemp. Hygrothermal simulations determine the minimum Z-value ratio between these materials with vapour versus wind barriers in temperate and cold climates. Wind barriers with Z-values between 1 and 8 GPa s m2/kg were used in walls with U-values of 0.15 and 0.10 W/m2 K. The indoor moisture load was defined from classes of 1 to 5 with a U-value of 0.15 W/m2 K and classes of 2 and 3 were used for a U-value of 0.10 W/m2 K. The Z-value ratio depends on the Z-values of the wind barrier and thermal insulation material, moisture load class, and U-value. The required Z-value ratio declines with an increased wind-barrier Z-value. The vapour-barrier Z-value approaches a fixed threshold for wind-barrier Z-values approaching lower values (1 GPa s m2/kg) and those approaching higher values (8 GPa s m2/kg), depending on the thermal insulation material. This parameter study examines wind barriers with a Z-value ranging between 1 and 8 GPa s m2/kg, which characterises typical wind barriers used in Denmark For the water-vapour diffusion resistance requirement of the vapour barrier, the Z-value increases for increased moisture load classes and thermally insulated walls with lower U-values. The conversion between the Z-value, the Sd-value, and the water-vapour resistance factor µ can be found in DS/EN ISO 12572:2016. [ABSTRACT FROM AUTHOR]

Published

2024

10. Atomistic simulations of calcium aluminosilicate interfaced with liquid water.

Author

Vuković, F., Garcia, N. A., Perera, S., Turchi, M., Andersson, M. P., Solvang, M., Raiteri, P., and Walsh, T. R.

Subjects

*CALCIUM, *MOLECULAR dynamics, *STONE, *WOOL, *MINERAL wool, *GLASS fibers, *LIQUID surfaces

Abstract

The dissolution behavior of calcium aluminosilicate based glass fibers, such as stone wool fibers, is an important consideration in mineral wool applications for both the longevity of the mineral wool products in humid environments and limiting the health impacts of released and inhaled fibers from the mineral wool product. Balancing these factors requires a molecular-level understanding of calcium aluminosilicate glass dissolution mechanisms, details that are challenging to resolve with experiment alone. Molecular dynamics simulations are a powerful tool capable of providing complementary atomistic insights regarding dissolution; however, they require force fields capable of describing not-only the calcium aluminosilicate surface structure but also the interactions relevant to dissolution phenomena. Here, a new force field capable of describing amorphous calcium aluminosilicate surfaces interfaced with liquid water is developed by fitting parameters to experimental and first principles simulation data of the relevant oxide-water interfaces, including ab initio molecular dynamics simulations performed for this work for the wüstite and periclase interfaces. Simulations of a calcium aluminosilicate surface interfaced with liquid water were used to test this new force field, suggesting moderate ingress of water into the porous glass interface. This design of the force field opens a new avenue for the further study of calcium and network-modifier dissolution phenomena in calcium aluminosilicate glasses and stone wool fibers at liquid water interfaces. [ABSTRACT FROM AUTHOR]

Published

2023

11. How reliable is the X‐ray fluorescence‐based differentiation between glass wool and rock wool and the age classification of rock wool?

Author

Paul, Andrea, Liestmann, Zoe, Zaenker, Steffen, Vogel, Kristin, Broszies, Tanja, and Ostermann, Markus

Subjects

*MINERAL wool, *MATERIALS handling, *MINERAL collecting, *GEOLOGICAL time scales, *DATABASES

Abstract

A prerequisite for the recycling of mineral wool is information about the type of material, that is, whether it is glass wool or rock wool. As mineral wool produced before the year 2000 can be potentially carcinogenic, it is furthermore important to distinguish between “old” and “new” wool when handling the material. Based on VDI 3492, it is possible to determine the material and, in the case of rock wool, the age by analyzing the mass fractions of eight oxides, which are the main components of mineral wool. This study presents the X‐ray fluorescence (XRF) analyses of 141 man‐made mineral fibers collected in Germany. Only in a few cases it was not possible to clearly assign the material type. In contrast, the identification of “old” and “new” rock wool posed a challenge as there were many borderline samples. Based on the available data, a chemometric model was developed that can classify “old” and “new” RW with a sensitivity of 93% and 89% and with a specificity of 100% in both cases. However, care must be taken when oxide contents are close to the specification limits. The reason for this mainly lies in the overlapping intervals of key oxides as suggested by VDI 3492, and, to a lesser extent, in the uncertainties typically occurring in the XRF‐based analysis of oxides. With this study, a comprehensive collection and evaluation of XRF data on mineral wool is made available, which can serve as a reference database for future users. [ABSTRACT FROM AUTHOR]

Published

2024

12. Hygrothermal assessment of three bio-based insulation systems for internal retrofitting solid masonry walls.

Author

Jensen, Nickolaj Feldt, Møller, Eva B., Hansen, Kurt Kielsgaard, and Rode, Carsten

Subjects

*VAPOR barriers, *INSULATING materials, *MINERAL wool, *RAINFALL, *MASONRY, *HYGROTHERMOELASTICITY

Abstract

The present project investigated the hygrothermal performance and risk of mould growth in solid masonry walls retrofitted internally with three diffusion-open bio-based insulation materials (two loose-fill cellulose and one hemp fibre), installed in test containers with controlled indoor climate. Focus was on bio-based insulation materials, as these are upcoming due to necessary CO2 reductions and because the hygroscopic properties of bio-based materials are different from traditional insulation materials like mineral wool therefore, some manufacturers claim a vapour barrier is unnecessary, even in relatively cold climates. The project was a large experimental study in two reefer containers with reconfigured facades, in which solid masonry walls with embedded wooden elements were constructed. The study focused on the conditions in the masonry/insulation interface and in the embedded wooden elements. The effect of hydrophobization and different indoor moisture loads were also investigated. Moreover, the bio-based insulation systems were compared with a wall insulated with the traditional mineral wool and vapour barrier system. Relative humidity and temperature were measured at several locations in the test walls for 1 year and 9 months. Measurements show that exposed masonry walls retrofitted internally with diffusion-open bio-based insulation materials resulted in unacceptably high moisture levels (>80% RH over longer periods). Lower moisture levels were observed when the internal insulation was combined with hydrophobization against wind-driven rain, but unacceptably high moisture levels still occurred (60%–70% in summer and 95%–100% in winter in the interface). Hydrophobization reduced the moisture levels in the interface and embedded wooden elements only in walls facing southwest, which is the direction with the most wind-driven rain. Mould growth tests showed no growth in the interface in walls insulated with cellulose insulation (mycometer surface value <25). Meanwhile growth was found in all four walls insulated with hemp fibre matts (mycometer surface value >400). [ABSTRACT FROM AUTHOR]

Published

2024

13. Recycling of mineral wool waste as supplementary cementitious material through thermochemical treatment.

Author

Doschek-Held, Klaus, Krammer, Anna Christine, Steindl, Florian Roman, Sattler, Theresa, and Juhart, Joachim

Subjects

MINE waste, GLASS recycling, MINERAL wool, HAZARDOUS wastes, INSULATING materials

Abstract

Mineral wool is commonly used in construction as thermal insulation material. After the product's lifetime, it is classified as hazardous waste if no trademark of the European Certification Board for Mineral Wool Products (EUCEB) or the German Institute for Quality Assurance and Labelling (RAL) exists. Mineral Wool Waste (MWW) is typically landfilled in Europe, which is challenging due to its low bulk density and dimensional stability. This circumstance highlights the need for alternative recycling methods that increase the recycling rate of construction and demolition (C&D) waste. This article outlines the recycling opportunities of MWW and focuses on the use of thermochemical treatment of different mixtures of input materials to produce a supplementary cementitious material (SCM). The material characterisation results and investigations on the binder suitability demonstrate that the slag fractions after the thermochemical treatment are well-qualified to be used as reactive binder components. Additionally, a material flow analysis was conducted to estimate the substitution potential of MWW as SCM in the Austrian cement industry. [ABSTRACT FROM AUTHOR]

Published

2024

14. Influence of Fe x O y and Al 2 O 3 Contents on the Thermal Stability of Iron Ore-Waste Fibers: Key Mechanisms and Control.

Author

Li, Xiaoguang, Wang, Xiaohui, Fang, Xianju, Shen, Xianglong, Huang, Liding, Qin, Jinyi, Fu, Wanzhang, and Li, Weiguang

Subjects

*GLASS transition temperature, *GLASS fibers, *ALUMINUM oxide, *MINERAL wool, *THERMAL stability

Abstract

Traditional rock wool fibres are susceptible to crystallization and pulverization. To mitigate this, glass fibres were produced from iron ore waste (IOW). When the ratio of Fe2+ and Fe3+ is 1:3 and the Al2O3 content is 10 wt.%, increasing the FexOy content enhances the thermal stability.At an FexOy content of 17–19% and an Al2O3 content of 10–13%, the glass transition temperature (Tg) peaked. Increasing the FexOy content from 10% to 20% enhanced the stability of Si-O and Al-O bonds and increased bridged oxygen, stabilizing the structure. Here, Fe2+ balances structural charges, while Fe3+ replaces some Al atoms in the network. When the Al2O3 content is 10–13% and the FexOy content is 17–19%, the thermal stability of the IOW rock glass reaches its optimal level. At 20% FexOy content, the structure becomes three-dimensional and cyclic, increasing polymerization. Consequently, incorporating FexOy alongside a 10% Al2O3 content improves thermal stability, supporting the development of high-stability rock wool from IOW. This approach also enhances the refractory properties of rock wool fibres within the FexOy-Al2O3-SiO2-MgO-CaO system. [ABSTRACT FROM AUTHOR]

Published

2024

15. Study on the Influence of Waste Rock Wool on the Properties of Cement Mortar under the Dual Fiber Effect of Polyvinyl Alcohol Fibers and Steel Fibers.

Author

Lu, Shijian, Cheng, Jiajia, Zhu, Zhipeng, Yan, Luchao, Wang, Yang, Xu, Lingling, and Deng, Min

Subjects

*MINERAL wool, *ROCK texture, *ROCK properties, *POLYVINYL alcohol, *ABRASION resistance, *MORTAR

Abstract

In this paper, the effect of waste rock-wool dosage on the workability, mechanical strength, abrasion resistance, toughness and hydration products of PVA and steel fiber-reinforced mortars was investigated. The results showed that the fluidity of the mortar gradually decreased with the increase in the dosage of waste rock wool, with a maximum reduction of 10% at a dosage of 20%. The higher the dosage of waste rock wool, the greater the reduction in compressive strength. The effect of waste rock wool on strength reduction decreases with increasing age. When the dosage of waste rock wool was 10%, the 28 days of flexural and compressive strengths were reduced by 4.73% and 10.59%, respectively. As the dosage of waste rock wool increased, the flexural-to-compressive ratio increased, and at 20%, the maximum value of 28 days of flexural-to-compressive ratio was 0.210, which was increased by 28.05%. At a 5% dosage, the abraded volume was reduced from 500 mm3 to 376 mm3—a reduction of 24.8%. Waste rock wool only affects the hydration process and does not cause a change in the type of hydration products. It promotes the hydration of the cementitious material system at low dosages and exhibits an inhibitory effect at high dosages. [ABSTRACT FROM AUTHOR]

Published

2024

16. Properties of Organic Matter in Composts Based on Sewage Sludge.

Author

Myszura-Dymek, Magdalena

Subjects

SLUDGE composting, SEWAGE sludge, PROPERTIES of matter, SEWAGE disposal plants, COMPOSTING, FLY ash

Abstract

The aim of the research was to assess the quality of organic matter contained in sewage sludge composting products and their co-composting with fly ash and mineral wool. The object of the research were composts produced using stabilized sewage sludge from the municipal sewage treatment plant (SS_1C) and sewage sludge with the addition of 20% (SSF_2C) and 30% (SSF_3C) of fly ash and 5% (SSW_4C) and 10% (SSW_5C) of mineral wool. Selected physicochemical properties, fractional composition of humic compounds, and the degree and rate of humification were determined in compost samples taken after 180 days of composting. The reaction of the evaluated composts was close to optimal for mature composts. Co-composting of sewage sludge with mineral wool and ash increased the sorption capacity in composts compared to SS_1C. Due to the content of available P and Mg, the discussed composts formed the SS_1C>SSF_2C and SSF_3C>SSW_4C and SSW_5C series. However, in terms of available K content: SSF_2C and SSF_3C>SSW_4C and SSW_5C>SS_1C. In the SS_1C compost the organic carbon (TOC) content was slightly higher, but no statistically significant effect of the addition of fly ash and mineral wool on the TOC content in mature composts was confirmed. The addition of ash and mineral wool significantly increased the total nitrogen content. Due to the humification index, the composts formed the series: SSW_4C > SSW_5C > SSF_2C > SS_1C > SSF_3C. The values of the C-KH/C-KF ratio in SS_1C were typical for good quality soils, while in the remaining composts the C-KH/C-KF values were slightly lower. The degree of humification of the assessed composts was characterized by poorly humified organic materials, with the highest values of this indicator found in composts with the addition of mineral wool. The assessed quality indicators of organic matter indicate that the organic matter of composts from sewage sludge with the addition of mineral wool and 100% sludge was of the highest quality. [ABSTRACT FROM AUTHOR]

Published

2024

17. Odporność ogniowa uszczelnień złączy liniowych w zależności od szerokości zabezpieczanego złącza oraz rodzaju zastosowanej wełny mineralnej.

Author

Sędłak, Bartłomiej, Izydorczyk, Daniel, and Sulik, Paweł

Abstract

Copyright of Materiały Budowlane is the property of Wydawnictwo SIGMA-NOT and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

18. Oil and Gas Structures: Forecasting the Fire Resistance of Steel Structures with Fire Protection under Hydrocarbon Fire Conditions.

Author

Gravit, Marina, Dmitriev, Ivan, Shcheglov, Nikita, and Radaev, Anton

Subjects

*FIRE testing, *FIRE prevention, *PETROLEUM industry, *CRITICAL temperature, *STEEL, *HEAT conduction, *EPOXY coatings

Abstract

The hydrocarbon temperature–time curve is widely used instead of the standard curve to describe the temperature in the environment of structural surfaces exposed to fire in oil and gas chemical facilities and tunnels. This paper presents calculations of the ratio of time to reach critical temperatures at different nominal fire curves for steel structures such as bulkheads and columns with different types of fireproofing. The thermophysical properties of the fireproofing materials were obtained by solving the inverse heat conduction problem using computer simulation. It was found that the time interval for reaching critical temperatures in structures with different types of fireproofing in a hydrocarbon fire decreased, on average, by a factor of 1.2–1.7 compared to the results of standard fire tests. For example, for decks and bulkheads with mineral wool fireproofing, the K-factor of the ratio of the time for reaching the critical temperature of steel under the standard curve to the hydrocarbon curve was 1.30–1.62; for plaster, it was 1.56; for cement boards, it was 1.34; for non-combustible coatings, it was 1.38–2.0; and, for epoxy paints, it was 1.71. The recommended values of the K-factor for fire resistance up to 180 min (incl.) were 1.7 and, after 180 min, 1.2. The obtained dependencies would allow fireproofing manufacturers to predict the insulation thickness for expensive hydrocarbon fire experiments if the results of fire tests under standard (cellulosic) conditions are known. [ABSTRACT FROM AUTHOR]

Published

2024

19. Hygrothermal Properties and Performance of Bio-Based Insulation Materials Locally Sourced in Sweden.

Author

Ranefjärd, Oskar, Strandberg-de Bruijn, Paulien B., and Wadsö, Lars

Subjects

*INSULATING materials, *THERMAL insulation, *EXTERIOR walls, *THERMAL conductivity, *HEAT capacity, *MINERAL wool, *RENEWABLE natural resources

Abstract

In recent years, there has been a paradigm shift in the building sector towards more sustainable, resource efficient, and renewable materials. Bio-based insulation derived from renewable resources, such as plant or animal fibres, is one promising group of such materials. Compared to mineral wool and polystyrene-based insulation materials, these bio-based insulation materials generally have a slightly higher thermal conductivity, and they are significantly more hygroscopic, two factors that need to be considered when using these bio-based insulation materials. This study assesses the hygrothermal properties of three bio-based insulation materials: eelgrass, grass, and wood fibre. All three have the potential to be locally sourced in Sweden. Mineral wool (stone wool) was used as a reference material. Hygrothermal material properties were measured with dynamic vapour sorption (DVS), transient plane source (TPS), and sorption calorimetry. Moisture buffering of the insulation materials was assessed, and their thermal insulation capacity was tested on a building component level in a hot box that exposed the materials to a steady-state climate, simulating in-use conditions in, e.g., an external wall. The tested bio-based insulation materials have significantly different sorption properties to stone wool and have higher thermal conductivity than what the manufacturers declared. The hot-box experiments showed that the insulating capacity of the bio-based insulators cannot be reliably calculated from the measured thermal conductivity alone. The results of this study could be used as input data for numerical simulations and analyses of the thermal and hygroscopic behaviour of these bio-based insulation materials. [ABSTRACT FROM AUTHOR]

Published

2024

20. Composting of recovered rock wool from hydroponics for the production of soil amendment.

Author

Istenič, Darja, Prosenc, Franja, Zupanc, Neva, Turel, Matejka, Holobar, Andrej, Milačič, Radmila, Marković, Stefan, and Mihelič, Rok

Subjects

SOIL amendments, MINERAL wool, COMPOSTING, HYDROPONICS, AQUATIC plants

Abstract

Due to its fibrous structure and high water holding capacity, rock mineral wool (RMW) has boosted the development of hydroponics. Consequently, the amount of waste RMW has also increased tremendously, which has stimulated the research and development of RMW reuse options. In this study, composting and degradability of RMW from hydroponics (gRMW) were tested in combination with different ratios of biowaste compost, including physical and chemical properties of the starting and final materials, and potential ecological hazards of the final product. gRMW had high water holding capacity and low organic matter content, which was easily degradable. Limits of toxic elements according to EU regulation were not exceeded. Degraded gRMW mixtures with compost did not exhibit toxicity to plants or aquatic bacteria and showed intermediate or limited habitat function for earthworms, which preferred the sole gRMW not mixed with compost. Overall, degraded gRMW exhibited parameters of safe soil amendment. [ABSTRACT FROM AUTHOR]

Published

2024

21. Comparative Study on Selected Insulating Materials for Industrial Piping.

Author

Porzuczek, Jan

Subjects

*INSULATING materials, *THERMAL conductivity, *URETHANE foam, *INDUSTRIALISM, *SYSTEMS availability

Abstract

This paper describes the results of an experimental assessment of the thermal conductivity of pipe insulation. The need for reducing energy loss in industrial piping systems makes the availability of relevant and reliable insulation materials of special importance. Several specimens of pipe laggings, made of different materials, including mineral wool, polyethylene foam (PEF), expanded polystyrene (EPS), flexible elastomeric foam (FEF) and polyurethane foam (PUR), were tested in accordance with the European standard ISO 8497. The thermal conductivity of the materials was measured for a wide range of temperatures. The results were compared with the values reported in the technical specifications as well as with the literature data. The assessment of measurement uncertainty was also described. The results showed that, in a few cases, thermal conductivity turned out to be greater than that declared by the manufacturer by as much as over 10%. [ABSTRACT FROM AUTHOR]

Published

2024

22. Use of Organo-Inorganic Binder in the Composition of Mineral Wool Products.

Author

Matyukhin, V. I., Ulomskii, V. A., and Matyukhina, A. V.

Subjects

*PHENOLIC resins, *CHELATES, *HEAT treatment, *MINERAL wool, *THERMAL insulation, *SOLUBLE glass

Abstract

The main purpose of a liquid binder in the composition of mineral wool products is to bond individual fibers to each other to create a strong and elastic structure. The combined use of an organic (phenol-formaldehyde resin) and an inorganic binder based on cold dissolution liquid glass is accompanied during their mechanical mixing by the formation of complex carbon-silicon compounds, which stabilize the formation of chelate compounds with an orienting effect of silicon ion during heat treatment, converting the polymer structure to a more ordered and dense structure with additional bridging hydrogen bonds. This process is accompanied by the parallel development of a polycondensation reaction of the organic binder and methylol groups and curing of the liquid glass. The presence of intramolecular bonds between the organic and inorganic parts of the binder increases the bond strength of the mineral fibers when forming the structure of fibrous thermal insulation materials by 20 – 30% with a slight increase in their water absorption. Limited use of cold dissolution liquid glass additives (not more than 0.4%) allows a reduction in the total consumption of organic binder by 20 – 25% with the possibility of reducing the required amount of mineral part by up to 10 – 15% while maintaining the required strength and operational properties of finished heat-insulating products. [ABSTRACT FROM AUTHOR]

Published

2024

23. Dissolution behavior of stone wool fibers in synthetic lung fluids: Impact of iron oxidation state changes induced by heat treatment for binder removal.

Author

Okhrimenko, D.V., Rasmussen, K.H., Bøtner, J.A., Ceccato, M., Foss, M., and Solvang, M.

Subjects

*HEAT treatment, *IRON oxidation, *SYNTHETIC fibers, *OXIDATION states, *FLUIDS, *WOOL, *CITRATES

Abstract

Stone wool fiber materials are commonly used for thermal and acoustic insulation, horticulture and filler purposes. Biosolubility of the stone wool fiber (SWF) materials accessed through acellular in vitro dissolution tests can potentially be used in future as an indicator of fiber biopersistence in vivo. To correlate acellular in vitro studies with in vivo and epidemiological investigations, not only a robust dissolution procedure is needed, but fundamental understanding of fiber behavior during sample preparation and dissolution is required. We investigated the influence of heat treatment procedure for binder removal on the SWF iron oxidation state as well as on the SWF dissolution behavior in simulant lung fluids (with and without complexing agents). We used heat treatments at 450 °C for 5 min and 590 °C for 1 h. Both procedures resulted in complete binder removal from the SWF. Changes of iron oxidation state were moderate if binder was removed at 450 °C for 5 min, and there were no substantial changes of SWF's dissolution behavior in all investigated fluids after this heat treatment. In contrast, if binder was removed at 590 °C for 1 h, complete Fe(II) oxidation to Fe(III) was observed and significant increase of dissolution was shown in fluids without complexing agent (citrate). PHREEQC solution speciation modeling showed that in this case, released Fe(III) may form ferrihydrite precipitate in the solution. Precipitation of ferrihydrite solid phase leads to removal of iron cations from the solution, thus shifting reaction towards the dissolution products and increasing total mass loss of fiber samples. This effect is not observed for heat treated fibers if citrate is present in the fluid, because Fe(III) binds with citrate and remains mobile in the solution. Therefore, for developing the most accurate SWF in vitro acellular biosolubility test, SWF heat treatment for binder removal is not recommended in combination with dissolution testing in fluids without citrate as a complexing agent. • Excessive heat treatment for binder removal oxidizes Fe(II) to Fe(III) in the SWF. • Fe(III) formation may alter SWF dissolution behavior in certain simulant lung fluids (i.e. PSF). • For in vitro acellular SWF biosolubility testing heat treatment for binder removal should be avoided. [ABSTRACT FROM AUTHOR]

Published

2024

24. Physicochemical properties and radiological hazards evaluations of some inorganic materials used in soilless agriculture.

Author

Eke, Canel and Ozaydin Ozkara, Reyhan

Subjects

HYDROPONICS, MEERSCHAUM, MINERAL wool, PERLITE, ELECTRIC conductivity, PHOSPHORUS in water, POTASSIUM

Abstract

This study aims to examine the physicochemical and radiological properties of some inorganic materials which are perlite, vermiculite, pumice, rock wool, zeolite, expanded clay aggregate, volcanic tuff, and sepiolite used in soilless agriculture. Water saturation, pH, electrical conductivity, calcium carbonate equivalent, available potassium, available phosphorus, and organic matter analyses were implemented for inorganic materials. The elemental contents of the components for studied inorganic materials were obtained using inductively coupled plasma‐optical emission spectrometry (ICP‐OES). Furthermore, natural and artificial radionuclides of studied inorganic materials were calculated using gamma‐ray spectrometry. The pumice has the highest 226Ra activity concentration, and the zeolite has the highest 232Th and 40K activity concentrations. The 137Cs activity concentration is the maximum for perlite and it is the minimum for expanded clay aggregate. The zeolite has the highest radiological hazard parameters whereas those are the smallest for the rock wool. The Fe, Na, B, Ca, K, Si, P, S, and Mn are the primary components of the inorganic materials used in soilless agriculture. Consequently, this study is contributed to environmental and health problems of livings. In the future, transferred radionuclides from plant to livings assessment can be carried out for these inorganic materials used in soilless agriculture. [ABSTRACT FROM AUTHOR]

Published

2024

25. Optimizing the Thickness of Multilayer Thermal Insulation on Different Pipelines for Minimizing Overall Cost-Associated Heat Loss.

Author

Alrasheed, Mohammed R. A.

Subjects

THERMAL insulation, HEAT losses, COST functions, MINERAL wool, CALCIUM silicates, LIFE cycle costing

Abstract

Optimizing the multilayer thermal insulation of pipelines transporting liquids and gases at higher than ambient temperatures is crucial for heat energy conservation and cost optimization. This study utilizes a multi-objective genetic algorithm to optimize the multilayer thermal insulation thickness around a pipe carrying fluid to minimize heat loss and associated costs. The model adopted mathematical associations between design variables and the overall installation cost of layers over a pipe from the available literature. The proposed model considered one or more insulation layers of rock wool and calcium silicate to oil pipelines containing steam, furfural, reduced crude or 300-distillate oil. All calculations considered fixed-charge rates as a fraction of 1 or 0.15. The results were compared with standard values and those predicted by other researchers in the literature. For the steam line, the standard insulation thickness was 50 mm, jumping to 327 mm for rock wool and 232 mm for calcium silicate. However, it decreased to 38 mm for double-layer calcium silicate and 138 mm for double-layer rock wool. For furfural, the insulation thickness was 40 mm, which rose to 159 mm for rock wool and 112 mm for calcium silicate. In general, for all four cases, the results show that using normal insulation thickness is inadequate and not economical. For example, for 300-distillate oil, the present practice puts the cost function at 54 USD/m, which drops to 20 USD/m for rock wool and 24 USD/m each for single-layer silicate and double-layer insulation. This amounts to almost 60% cost savings. Similar trends are observed for the other three cases. This model can provide up to 60% savings in cost and a 92% reduction in heat loss at optimum insulation thickness compared to other models. [ABSTRACT FROM AUTHOR]

Published

2024

26. The Effect of Mineral Wool Fiber Additive on Several Mechanical Properties and Thermal Conductivity in Geopolymer Binder.

Author

Łaźniewska-Piekarczyk, Beata and Smyczek, Dominik

Subjects

*THERMAL properties, *MINERAL wool, *THERMAL conductivity, *MINE waste, *FLEXURAL strength, *WOOL

Abstract

The article discusses the effect of additives of waste mineral wool fibers on geopolymer binder. This is an important study in terms of the possibility of recycling mineral wool waste. The paper describes an effective method for pulverizing the wool and the methodology for forming geopolymer samples, labeled G1 for glass-wool-based geopolymer and G2 for stone-wool-based geopolymer. The compressive and flexural strengths and thermal conductivity coefficient of the geopolymer with the addition of mineral fibers were determined. The key element of the article is to verify whether the addition of mineral wool fibers positively affects the properties of the geopolymer. The results obtained prove that the addition of fibers significantly improves the flexural strength. For the G1 formulation, the ratio of compressive strength to flexural strength is 18.7%. However, for G2 samples, an even better ratio of compressive strength to flexural strength values of 26.3% was obtained. The average thermal conductivity coefficient obtained was 1.053 W/(m·K) for the G1 series samples and 0.953 W/(m·K) for the G2 series samples. The conclusions obtained show a correlation between the porosity and compressive strength and thermal conductivity coefficient. The higher the porosity, the better the thermal insulation of the material and the weaker the compressive strength. [ABSTRACT FROM AUTHOR]

Published

2024

27. Analysis of the physical-mechanical performance of the concrete partially substituting the cement by nanosilica and the coarse aggregate by rock wool.

Author

Nicolle Bravo, Anghela, Jhon Gallardo, Wily, Pedro Muñoz, Socrates, Dante Rodriguez, Ernesto, and Pierre Fernández, Jean

Subjects

*RESOURCE exploitation, *MINERAL wool, *PHYSICAL mobility, *CONCRETE, *CEMENT

Abstract

The excessive production of concrete has led to the overexploitation of natural resources, prompting the exploration of high-strength alternative materials like nanosilica (NS) as a superplasticizer substituting cement and rock wool (LR) used in bulk as a partial substitute for coarse aggregate. In this experimental study, both materials are proposed to be incorporated into concrete production with varying percentages: 0.6%, 0.8%, 1.0%, and 1.4% of NS by weight, and 2%, 4%, 6%, and 8% of LR by volume. The objective is to evaluate their physical and mechanical performance, including settlement properties, air content, and mechanical strength. The results indicated a significant increase in settlement with NS, reaching up to 8". Air content decreased to 0.7% with 0.8NS but increased with LR. Additionally, at 28 days, compression resistance increased by 37.19% and 30.53% for C-1 and C-2, respectively, with 1.4%NS compared to the control model. Furthermore, with 1.4%NS+6%LR, it increased by 21.85%. In traction, samples with 1.4%NS increased by 24.10%, and those with more than 6%LR increased by 16.57%. Furthermore, flexion increased by 18.84% for 1.4%NS and 26.68% for 1.4NS+8LR. The study concludes that the optimal addition is 1.4% NS and 6% LR, significantly enhancing the mechanical resistance of concrete compared to control designs. [ABSTRACT FROM AUTHOR]

Published

2024

28. Thermal Bridging and its Mitigation in Bamboo Panel Construction with Steel Frameworks and Mineral Wool Insulation.

Author

Haidong Li, Wenjun Zhang, Yunxing Zhang, Feifei Zhai, and Fuming Chen

Subjects

*STRUCTURAL panels, *MINERAL wool, *BAMBOO, *WALL panels, *EXTERIOR walls, *FINITE element method, *STEEL, *BUILDING-integrated photovoltaic systems

Abstract

An energy-efficient and environmentally conscious bamboo-constructed residential structure was created, comprising bamboo composite panels, steel framework, and mineral wool insulation. To ascertain the efficacy of this particular type of wall in enhancing thermal capabilities, the finite element method was employed to analyze the factors influencing the thermal performance of the exterior wall panels, insulation layer, framework, and interior wall panels. A more judicious design and implementation strategy, known as the 3# and 8# combination scheme, was evaluated in practical applications to assess the thermal efficiency of the wall system. The findings indicated that augmenting the thickness of the inner and outer wall panels and insulation layer, reducing the framework thickness, and incorporating wooden framework as a substitute for steel framework within a certain range enhanced the thermal capabilities of bamboo-constructed walls and mitigated the adverse effects of thermal bridges. The thermal performance of the residences employing the newly developed bamboo-constructed walls surpassed that of conventional iron container houses, thereby warranting broader adoption and application in practical projects. These outcomes offer valuable insights for the optimized design of thermal performance in bamboo-constructed walls. [ABSTRACT FROM AUTHOR]

Published

2024

29. Effect of Coke Oxidation Kinetics on Mineral Wool Cupola Performance.

Author

Matyukhin, V. I., Matyukhina, A. V., and Punenkov, S. E.

Subjects

*COKE (Coal product), *OXIDATION kinetics, *MINERAL wool, *DOMES (Architecture), *HEAT of combustion, *FURNACE atomic absorption spectroscopy

Abstract

In order to evaluate the effect of impact of the nature of solid fuel on performance indicators of a shaft melting furnace of the cupola type with an internal diameter of 2200 mm and a layer height of 4.5 m, and conditions for its oxidation, the real range of change in the properties of industrial coke batches of various manufacturers is determined (8 varieties) under conditions of non-oxidation heating of coke samples in an argon atmosphere at the rate of 5 deg/min to a temperature of 1000°C and isothermal exposure in an air atmosphere. Operating conditions of the mine unit on these cokes are evaluated with respect to values of specific coke consumption, mineral melt yield, thermal efficiency and changes in conditions for development of heat transfer from gases to materials based upon the ratio of heat capacities of their flows obtained from industrial tests. It is shown that an increase in the complete coke oxidation interval from 7 to 12.5 – 13.0 min will provide a decrease in specific coke consumption from 265 to 225 kg/ton of melt, i.e., by 15.9%, an increase in yield of mineral melt from 25.3 to 30.02%, i.e., by 18.66%, with a decrease in cupola total thermal efficiency from 61.7 to 60.2%, i.e., by 1,5%. For this it is advisable to use coke with maximum heat of combustion. Use of coke mineral raw material during melting, which has a rate of change of sample weight from 5.0 up to 8.0 – 8.5%/min (more active coke), provides a coke minimum specific consumption at the level of 224 kg/ton of melt with a maximum yield of molten smelting product of at least 29.8% of the weight of the initial components with unit thermal efficiency at 61.7%. For this it is necessary to use more active coke with respect to blast oxygen. Heat transfer process conditions from gases to materials during smelting are characterized by low intensity with the lowest ratio of heat capacities of material and gas flows not lower than 0.827 in the range of complete coke oxidation 12.5 – 13.0 min and an average rate of change in sample weight of about 6.0%/min. [ABSTRACT FROM AUTHOR]

Published

2024

30. 岩棉复合保温外模板承载力及温度效应分析.

Author

赵建军, 付佳欣, and 李 爽

Subjects

MINERAL wool, TEMPERATURE effect

Abstract

Copyright of Journal of Harbin Institute of Technology. Social Sciences Edition / Haerbin Gongye Daxue Xuebao. Shehui Kexue Ban is the property of Harbin Institute of Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

31. Wpływ wymiarów izolacji z wełny mineralnej na odporność ogniową uszczelnień przejść stalowych rur przez pionowe przegrody przeciwpożarowe.

Author

Sędłak, Bartłomiej and Sulik, Paweł

Subjects

STEEL pipe, MINERAL wool

Abstract

Copyright of Materiały Budowlane is the property of Wydawnictwo SIGMA-NOT and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

32. Study of the deformation process of various types of thermal insulation materials under the influence of low temperatures and moisture

Author

E. N. Neverov, I. A. Korotkiy, P. S. Korotkih, A. N. Rasshchepkin, and S. A. Samar

Subjects

thermal insulation material, polyurethane foam, mineral wool, foam, polystyrene foam, deformation, refrigeration machine, Architecture, NA1-9428, Construction industry, HD9715-9717.5

Abstract

Introduction. Refrigerating machines are used in many areas of industry to produce artificial cold. To maintain optimal operating temperatures, increase energy efficiency and reduce energy loss, thermal insulation is used during the operation of refrigerating machines. Thermal insulation is the structural elements of the refrigerator, which reduce the heat transfer process, and plays the role of the main thermal resistance in the structure. The main characteristics of thermal insulation materials are: heat conductivity, density, moisture absorption, hydrophobicity, frost resistance, strength and flammability. Depending on the conditions in which the refrigerator will be located, it is possible to determine which material will be preferable as thermal insulation. At the moment, there are many thermal insulation materials, which in turn puts the consumer at a dead end, because in most cases, the description of the characteristics of this material provides information only about its positive qualities. At the same time, its other features, which make its use insufficiently effective, are kept silent.Materials and methods. In this article, the analysis of different types of thermal insulation materials, which are priority in the design of cold storage chambers, is carried out. In order to understand which material has the characteristics we need, it is necessary to recreate the conditions under which this material will be used. To do this, several basic laboratory influences are used to create unfavorable conditions for materials.Results. As a result of these interactions, tests were performed on materials that demonstrated the strengths and weaknesses of materials under different physical conditions.Conclusions. Based on the above results, it will become clear which materials are priority as thermal insulation of the refrigerator, and which need additional processing.

Published

2023

33. Design optimization of filled ceramic blocks.

Author

Stastnik, Stanislav and Prusa, David

Subjects

*THERMAL insulation, *BRICKS, *CERAMICS, *THERMAL conductivity measurement, *THERMAL resistance, *HEAT equation, *MINERAL wool

Abstract

Clay bricks are used as a material for building structures since ancient times, but new requirements are coming in terms of their thermal insulation properties now. This article presents the development tendencies of the material concept and geometric arrangement of ceramic masonry blocks made of fired clay with a thickness of 500 mm using a tongue-and-groove connection and thin-layer gluing with a horizontal load-bearing joint mortar. Numer-ical simulation according to the Fourier equation of heat propagation is used. The specific material properties are based on laboratory measurements of the coefficient of thermal conductivity of components used for incorporation in ceramic fittings, which affect its resulting thermal resistance. The concept of arranging ceramic fittings uses large internal cavities with air filling, foam silicate filling, light filling based on waste thermal insulation with silicate binder, mineral wool, polyurethane or aerogel insulation. The optimization approach seeks for the best geometric and material properties, maximizing the maximum value of thermal resistance of the masonry created from the assessed blocks. [ABSTRACT FROM AUTHOR]

Published

2023

34. Moisture Transport in Loose Fibrous Insulations under Steady-State Boundary Conditions.

Author

Kosiński, Piotr

Subjects

*MOISTURE, *CELLULOSE fibers, *WOOL, *THERMAL conductivity, *MINERAL wool, *WOOD

Abstract

This research aimed to compare the transport capacity of loose-fill mineral wool, cellulose fibers, and wood wool to transfer moisture under steady-state conditions. The tests were carried out in the heat flow meter apparatus, which created a constant thermal field, limiting samples of sorptive moistened materials. The thermal conductivity, stabilization time, and moisture content of the samples were measured. Based on the variation in the results, the dynamism of moisture transport in the materials was determined. Mineral wool samples showed the lowest sorption. As a result, the moisture transport in this material stopped the fastest. In the case of cellulose and wood fibers, moisture transport continued throughout the whole test procedure. It was noted that the amount of moisture transport is influenced primarily by the structure of the fibers, the moisture content, and the possible presence of air in the pores. The wetter the material, the faster the transport. The dynamism of moisture transport according to trends of thermal conductivity changes over time was analyzed. The greater the slope of the linear regression line, the greater the dynamics of change. The smallest dynamics of change were found for mineral wool, for which the measured slope was between −0.008 and −0.033. For cellulose and wood wool, the range of slope was from −0.141 to −0.210, and from −0.162 to −0.211, respectively. The results of this research may provide the basis for further work on buffering moisture in the adjacent internal layers of the frame walls. [ABSTRACT FROM AUTHOR]

Published

2023

35. Improving Energy Efficiency in a Building Using Passive Energy-Saving Measures.

Author

Stanca, Simona

Subjects

ENERGY conservation in buildings, ENERGY consumption, ENERGY consumption of buildings, RESOURCE exploitation, THERMAL insulation, BUILDING envelopes, MINERAL wool

Abstract

We are going through a time when environmental, economic and social concerns, intensely amplified by climate change, by the depletion of resources, are growing. In this context, setting targets such as reducing energy consumption in the buildings sector, energy efficiency, and the use of renewable energies are becoming a priority, both at national and international level. Improving the energy efficiency of the existing building stock is important, not only for achieving national medium-term energy efficiency targets, but also for meeting the long-term objectives of the strategy on climate change and the transition to a competitive low-carbon economy by 2050 (https://energy.ec.europa.eu/system/files/2014-11/2014%5farticle4%5fro%5fromania%5f0.pdf). Currently, the building is considered as a structure in a continuous evolution, which in time through maintenance, rehabilitation and modernization works will meet the requirements expressed by the user. The case study presented in the paper presents an analysis from the point of view of improving the energy efficiency, reducing the energy requirement in a building using passive energy-saving measures, that is, the additional thermal insulation of an element of the building envelope. The materials selected for this research are: expanded polystyrene, basaltic mineral wool and cellulose fibres. [ABSTRACT FROM AUTHOR]

Published

2023

36. Investigation of Preparation of Slag Wool from Melting-Separated Red Mud.

Author

Du, Peipei, Zhang, Yuzhu, Long, Yue, and Xing, Lei

Subjects

MINERAL wool, MUD, INORGANIC fibers, PRODUCT recovery, SAND

Abstract

The preparation of high-quality inorganic fibers by centrifugation from modified melting-separated red mud, which is the product of the efficient recovery of pig iron from red mud, is a new approach to achieve large-scale production of high value-added materials from red mud. This method has a wide range of application prospects and could contribute substantially to the comprehensive utilization of bulk industrial solid waste and the development of a circular economy. In this study, melting-separated red mud was modified with water-quenched blast furnace slag, quartz sand, and quicklime. The effect of the CaO/Na2O mass ratio on the viscosity, fluidity, and crystallization performance of the melting-separated red mud was investigated; slag wool was prepared by centrifugation under laboratory conditions; and the effect of the CaO/Na2O mass ratio on the morphology and properties of the slag wool was investigated. The viscosity of modified melting-separated red mud with different CaO/Na2O mass ratios shows a decreasing trend with increasing temperature, and the fluidity increases with increasing temperature, indicating that the melt fluidity is improved. The suitable fiber-forming temperature of the melting-separated red mud shows a trend of increasing–decreasing–increasing with an increasing CaO/Na2O mass ratio, and at a CaO/Na2O ratio of 3.0, the maximum suitable fiber-forming temperature is 81 °C. Considering the feasibility of slag wool preparation from modified melting-separated red mud, the CaO/Na2O of the modified raw material system should not be higher than 3.0. The crystallization temperature of modified melting-separated red mud with different CaO/Na2O mass ratios first increases and then decreases, with a peak of 1450 °C at a CaO/Na2O ratio of 4.0. Slag wool prepared from modified melting-separated red mud with different CaO/Na2O mass ratios exhibits good properties, with a diameter of 5.47–6.67 µm and a slag ball content of 2.7–8.4%. [ABSTRACT FROM AUTHOR]

Published

2023

37. Contribution of Various Loads to the Convex Shape of Rock Wool Insulation Slabs during Production.

Author

Hladnik, Jurij and Jerman, Boris

Subjects

*MINERAL wool, *MECHANICAL loads

Abstract

Rock wool insulation slabs are produced in special curing ovens, where molten rock wool fibres coated with binder are compressed between two slat conveyors and blown with hot air for vitrification. Often, the cross-section of the final slabs is slightly convex, which is undesirable. The degree of convexity depends on the deformation of the steel crossbars of the slat conveyors, which are subjected to combined pressure and nonlinear temperature loadings. Due to this complex loading state, it is difficult to determine the contribution of individual load to the total deformation. The main aim of the study was to determine these contributions. Temperature and stress measurements of the crossbars were performed during rock wool production. Upon collecting these measurements, a finite element (FE) model of a crossbar was established for the identification of the pressure loading acting on the crossbars, and finally for determination of their deformations. As a main result of the study, an inverse problem-based methodology for the identification of the deflection of a structure due to unknown temperature and pressure loadings was established and applied on the specific case. The deviations between the deformations of the FE crossbars and the final shape of the rock wool slabs were below 10%, which validates the novel methodology. [ABSTRACT FROM AUTHOR]

Published

2023

38. Rock Wool Fiber-Reinforced and Recycled Concrete Aggregate-Imbued Hot Asphalt Mixtures: Design and Moisture Susceptibility Evaluation.

Author

Hussein, Farah Khaleel, Ismael, Mohammed Qadir, and Huseien, Ghasan Fahim

Subjects

ASPHALT, FIBER-reinforced concrete, MINERAL wool, RECYCLED concrete aggregates, ASPHALT concrete, MOISTURE

Abstract

Designing asphalt mixtures for pavement construction by controlling the moisture-mediated damage remains challenging. With the progression of time, this type of damage can accelerate deterioration via fatigue cracking and rutting unless inhibited. In this study, two types of hot asphalt mixtures (HAMs) were made by incorporating recycled concrete aggregates (RCAs), which were reinforced with rock wool fibers (RWFs). The first specimen was a normal mixture with a completely virgin aggregate, and the second one was a sustainable mixture with 30% RCAs. The proposed mixes were thoroughly characterized to assess the impact of RWF incorporation at various contents (0.5, 1, 1.5, and 2%) on moisture resistance. The optimal asphalt concentration (OAC) and volumetric parameters of the mixes were determined using the Marshall technique. The moisture susceptibility of the obtained HAMs was evaluated in terms of the tensile strength ratio (TSR). The results revealed that the moisture resistance, Marshall stability, flow, and volumetric parameters of the HAMs were improved due to the reinforcement by RWFs, indicating a reduction in the moisture sensitivity and an increase in TSR%. In addition, the HAMs designed with 1.5% RWFs displayed the highest TSR% (11.37) and Marshall stability compared to the control mix. The observed improvement in the moisture resistance and Marshall attributes of the prepared HAMs was ascribed to the uniform distribution of the RWFs that caused a well-interconnected structure and tightening in the asphalt concrete matrix. It is asserted that the proposed HAMs can be nominated for the construction of durable high-performance pavements. [ABSTRACT FROM AUTHOR]

Published

2023

39. Effect of Coal Mining Waste and Its Mixtures with Sewage Sludge and Mineral Wool on Selected Properties of Degraded Anthropogenic Soil.

Author

Żukowska, Grażyna, Myszura-Dymek, Magdalena, Roszkowski, Szymon, and Bik-Małodzińska, Marta

Subjects

COAL mine waste, ANTHROPOGENIC soils, MINERAL wool, CIRCULAR economy, SOIL absorption & adsorption, NO-tillage, SEWAGE sludge

Abstract

The aim of the study was to evaluate the effect of coal mining waste and its mixtures with municipal sewage sludge and waste rock wool from cover crops on the formation of selected properties of degraded anthropogenic soil. Under the conditions of a pot experiment, coal mining waste and its mixtures with 2.5 and 5% sewage sludge and mixtures supplemented with 1% addition of waste rockwool from cover crops were introduced (in a ratio of 1:1) into the degraded anthropogenic soil. White mustard was grown on the substrates in the first year and maize in the second year. The pH, EC, and sorption properties were determined in soil samples taken before of the plants and after their harvest. The results showed that the addition of coal mining waste and its mixtures with municipal sewage sludge and waste rock wool improved the soil pH and sorption properties. The management of coal mining waste and waste optimising its properties for the production of fertilizing agents can be an effective strategy within a circular economy, which at the same time will increase the efficiency of the management of degraded and poor-quality soils. [ABSTRACT FROM AUTHOR]

Published

2023

40. A Study on the Applicability of Waste Glass Wool and Waste Mineral Wool as Fiber Reinforcement.

Author

Lim, Chi-Su, Jang, Dae-Seong, Kim, Jin-Cheol, Kim, Hong-Sam, and Lee, Jae-Jun

Subjects

GLASS waste, MINE waste, MINERAL wool, INDUSTRIAL wastes, FIBER cement, POWDERED glass, ELECTRIC insulators & insulation

Abstract

Recently, the handling of waste industrial resources has become an issue, and the importance of sustainable resources has increased. Among these waste industrial materials are glass wool and mineral wool, which are fibrous materials used as insulation materials with characteristics such as sound absorption, insulation, and non-flammability. However, after their service life, glass wool and mineral wool used for insulation are generally buried or incinerated, causing problems such as air and soil contamination. This research was conducted to examine the applicability of waste glass wool and mineral wool obtained from expired insulation as fiber reinforcement in cement concrete. The research aimed to evaluate the fresh concrete properties, strength properties, and durability properties by adding waste glass wool and waste mineral wool up to 0.5–2.0% of the cement weight. Regarding the slump and air content of fresh concrete, the results showed that the addition of waste fibers within this range did not significantly affect the air content. However, the slump decreased as the addition amount increased due to the high absorption, which is a characteristic of the fibers. In addition, the evaluation of strength revealed that the incorporation of fibers decreased the compressive strength compared to the reference concrete. However, the tensile strength increased due to the load-supporting function of the waste fibers. In the evaluation of freezing–thawing resistance and chloride ion penetration resistance, it was confirmed that the freezing–thawing resistance improved in all cases where waste glass wool was added. The chloride ion penetration resistance was found to be similar to that of the reference concrete. However, in the case of waste mineral wool, it was observed that an addition rate of more than 2.0% of fibers was required to ensure freezing–thawing resistance. As the addition rate increased, the total charge passed (permeability) increased significantly, leading to a decrease in chloride ion penetration resistance. [ABSTRACT FROM AUTHOR]

Published

2023

41. Mineral Wool Substitute: Polyiso in Above-grade Applications.

Author

Fantin, Greg

Subjects

MINERAL wool

Published

2024

42. Oil and Gas Structures: Forecasting the Fire Resistance of Steel Structures with Fire Protection under Hydrocarbon Fire Conditions

Author

Marina Gravit, Ivan Dmitriev, Nikita Shcheglov, and Anton Radaev

Subjects

oil and gas industry, fire safety, steel structures, fire resistance limit prediction, fire protection, mineral wool, Physics, QC1-999

Abstract

The hydrocarbon temperature–time curve is widely used instead of the standard curve to describe the temperature in the environment of structural surfaces exposed to fire in oil and gas chemical facilities and tunnels. This paper presents calculations of the ratio of time to reach critical temperatures at different nominal fire curves for steel structures such as bulkheads and columns with different types of fireproofing. The thermophysical properties of the fireproofing materials were obtained by solving the inverse heat conduction problem using computer simulation. It was found that the time interval for reaching critical temperatures in structures with different types of fireproofing in a hydrocarbon fire decreased, on average, by a factor of 1.2–1.7 compared to the results of standard fire tests. For example, for decks and bulkheads with mineral wool fireproofing, the K-factor of the ratio of the time for reaching the critical temperature of steel under the standard curve to the hydrocarbon curve was 1.30–1.62; for plaster, it was 1.56; for cement boards, it was 1.34; for non-combustible coatings, it was 1.38–2.0; and, for epoxy paints, it was 1.71. The recommended values of the K-factor for fire resistance up to 180 min (incl.) were 1.7 and, after 180 min, 1.2. The obtained dependencies would allow fireproofing manufacturers to predict the insulation thickness for expensive hydrocarbon fire experiments if the results of fire tests under standard (cellulosic) conditions are known.

Published

2024

43. Wastes from the production of heat-insulating basalt wool as an additive in cement-based materials

Author

Aleksandr Klyuev, Sergey Klyuev, Ekaterina Fomina, Elena Shorstova, Marina Ageeva, Igor Nedoseko, Linar Sabitov, Vitaly Shamanov, Rinat Shayakhmetov, and Yury Liseitsev

Subjects

Mineral wool, Active additive, Binder, Building material, Performance, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

The building materials science at the present stage is aimed at expanding the components of composites. At the same time, these components acquire special value with the simultaneous disposal of various wastes. One of such materials that have not been studied before are molten spherical basalt particles (beads) formed as waste in the production of heat-insulating materials. The aim of the article was to study the effect of balls on the structure formation of cement materials. The vibration spectra of basalt balls, which differ from the spectra of pure silica, were studied, which makes it possible to form silicates with different contents of aluminum and iron. The revealed features of the particle surface morphology, grain composition and the presence of amorphous silicate phases in this material confirm its effective use as an active mineral additive in cement concretes of normal and autoclaved hardening. The activity of this binder component is confirmed by the fact that after 180 min 15 mg/g calcium hydroxide is absorbed. SEM images confirmed compaction of the microstructure of cement composites containing crushed basalt granules. As a result of the use of this new additive, the compressive strength increases, while the maximum effect is achieved when 5–10% of finely ground basalt balls are introduced into the mixture. Amorphous quartz accelerates the pozzolanic reaction, increasing the packing density of hydration products. These basalt granules are able to accumulate water, which then takes part in the hydration reaction in a dosed manner. The increased water-holding capacity of the created binder creates conditions for the consistent growth of hydrated products and for synthesis with minimal internal stresses and volumetric deformations.

Published

2023

44. Influence of Profiled Faces on the Overall Shear Performance of Strongly Profiled Sandwich Panel with Mineral Wool Core.

Author

Silwal, Shekhar, Mela, Kristo, and Ma, Zhongcheng

Subjects

SANDWICH construction (Materials), MINERAL wool, CORE materials, STRESS concentration, SHEARING force

Abstract

The total shear force induced on a profiled sandwich panel by an external load is distributed between the profiled face and core. Sandwich panel with a discrete core material such as mineral wool consists of multiple transverse lamella joints across the full width of the panel, affecting the overall shear performance of the panel as these joints have negligible resistance to shear. Additionally, in some cases the core material is partially bonded only to the lower flange of the profiled face which increase the concentration of stresses in the bonded area leading to the crushing of the core on the support. This work studies the distribution of shear force in mineral wool core sandwich panels with one profiled face utilizing a shear beam test on a specimen cut from the panel including the profiled part. Based on the results and failure modes obtained, this work investigates the behavior and role of the profiled face on the shear resistance of profiled sandwich panels. The distributed shear force between the core and profiled part obtained from the shear beam tests are compared with full‐scale tests suggested by the European Standard EN 14509:2013, thus, exploring the applicability of the devised shear beam test method for assessing the shear properties of profiled sandwich panel. [ABSTRACT FROM AUTHOR]

Published

2023

45. Selected Properties of Soil-like Substrates Made from Mine Coal Waste and Their Effect on Plant Yields.

Author

Żukowska, Grażyna, Myszura-Dymek, Magdalena, Roszkowski, Szymon, and Olkiewicz, Magdalena

Abstract

To reduce the environmental damage caused by coal waste landfills, it is necessary to look for rational methods for their management. One method for their development is the creation of soil-like substrates. This study aimed to assess the properties of soil-like substrates from coal mining waste, combined with a varied sample of sewage sludge and waste mineral wool. The properties of the substrates were evaluated in a pot experiment. The properties of the substrates and their yield potential were determined. Coal mining waste as a substrate, compared to anthropogenic soil, was characterized by a significantly higher sorption capacity; the content of alkaline cations and pH; significantly higher contents of organic carbon, nitrogen, and available forms of K and Mg; and a lower content of available P. The substrates enriched with sewage sludge showed a significant increase in content of organic carbon, nitrogen, and assimilable forms of P and Mg, as well as the optimization of sorption properties. Extending the composition of substrates with mineral wool resulted in further improvement of their properties. The yields of plants grown on coal mining waste were significantly lower than those of those grown on anthropogenic soil. Substrates with sewage sludge and mineral wool had a significantly higher yield potential. [ABSTRACT FROM AUTHOR]

Published

2023

46. Exposure to MMVF in residential and commercial buildings: A literature review and quantitative synthesis.

Author

Allen, Laura H, Suder Egnot, Natalie, Allen, Hannah, Chan, Kathy, and Marsh, Gary

Subjects

*LITERATURE reviews, *PHASE-contrast microscopy, *DWELLINGS, *CERAMIC fibers, *TRANSMISSION electron microscopy, *COMMERCIAL buildings, *DETERIORATION of buildings

Abstract

Man-made vitreous fibers (MMVF) are a class of inorganic fibrous materials that include glass and mineral wools, continuous glass filaments, and refractory ceramic fibers valued for their insulative properties in high temperature applications. Potential health effects from occupational exposure to MMVF have been investigated since the 1970s, with focus on incidence of respiratory tract cancer among MMVF-exposed production workers. The general population may experience exposure to MMVF in residential and/or commercial buildings due to deterioration, construction, or other disruption of materials containing these fibers. Numerous studies have characterized potential exposures that may occur during material disruption or installation; however, fewer have aimed to measure background MMVF concentrations in residential and commercial spaces (i.e., non-production settings) to which the general population may be exposed. In this study, we reviewed and synthesized peer-reviewed studies that evaluated respirable MMVF exposure levels in non-production, indoor environments. Among studies that analyzed airborne respirable MMVF concentrations, 110-fold and 1.5-fold differences in estimated concentrations were observed for those studies utilizing phase contrast optical microscopy (PCOM) versus transmission electron microscopy (TEM) and scanning electron microscopy (SEM), respectively. A positive correlation was observed between respirable air concentrations of MMVF and total surface concentrations of MMVF in seldom-cleaned areas. Ultimately, available evidence suggests that both ambient air and surface concentrations of MMVF in indoor environments are consistently lower than exposure limits developed to prevent negative health outcomes among sensitive populations. [ABSTRACT FROM AUTHOR]

Published

2023

47. Determination of Thermal Properties of Mineral Wool Required for the Safety Analysis of Sandwich Panels Subjected to Fire Loads.

Author

Ablaoui, El Mehdi, Malendowski, Michał, Szymkuc, Wojciech, and Pozorski, Zbigniew

Subjects

*SANDWICH construction (Materials), *MINERAL wool, *MINERAL properties, *THERMAL properties, *THERMAL diffusivity

Abstract

The paper presents theoretical, experimental and numerical studies on the thermal behavior of mineral wool used in sandwich panels. The aim of this study is to investigate the thermal properties of mineral wool at elevated temperatures and provide a simple model that would allow us to determine the heat propagation in sandwich panels during a fire. The paper proposes a new method to experimentally evaluate thermal diffusivity, derived from theoretical premises. Experiments are conducted in a laboratory furnace where specimens are placed and temperatures inside specimens are measured. Different methods are used to process the test results and calculate the thermal diffusivity of mineral wool. Finally, a numerical analysis of heat transfer using the finite element method (FEM) is performed to validate the obtained thermal properties. [ABSTRACT FROM AUTHOR]

Published

2023

48. Change of the Mineral Wool Cupola Operating Conditions During the Transition from the Open Gas Flow Mechanism to the Closed One.

Author

Matyukhin, V. I. and Matyukhina, A. V.

Subjects

*GAS flow, *DOMES (Architecture), *MINERAL wool, *AIR flow, *WASTE gases

Abstract

The widespread industrial use of cupola-type shaft furnaces requires controlling their gas-dynamic and thermal behavior. When a cupola operates with an open top, its thermal regime is characterized mainly by the peripheral flow of gases with a significant difference in the ratio of the heat capacity of gas flows to material thermal capacity. The use of forced removal of exhaust gases from the shaft furnace contributes to an earlier transition from a peripheral to a predominantly central gas flow mechanism. By increasing the degree of rarefaction at the furnace top to 0.71 – 0.73 bar, it is possible to increase the melt temperature, pressure in the furnace cavity, temperature and air blast flow, as well as exhaust gas temperature while improving the conditions of heat transfer between gases and heated materials. A continuous decrease in the productivity of the unit accompanies this process, while the melting process stability improves. A further increase in the degree of rarefaction at the top contributes to a gradual transition from the peripheral to the central gas flow mechanism with a deterioration in cupola melting performance. [ABSTRACT FROM AUTHOR]

Published

2023

49. Initial evaluation of USP apparatus 4 for measuring dissolution profile of man-made vitreous fibers.

Author

Hoffman, J.W., Okhrimenko, D.V., Chaudan, E., Herault, Q., Drnovsek, N., Pezennec, E., Aznar, A., Mascaraque, N., Haddouchi, S., Lecluse, M., Badissi, A.A., de Cruz, J., Hiéronimus, L., and Solvang, M.

Subjects

*SYNTHETIC fibers, *FIBERS, *BUFFER solutions, *POTASSIUM phosphates, *MINERAL wool, *WOOL, *PACKAGING materials

Abstract

We report the successful evaluation of a US Pharmacopeia Apparatus 4 (USP-4) system in measuring the dissolution profiles of man-made vitreous fibers (MMVF) 1 1 Man-made vitreous fibers (MMVF) is the terminology commonly used in the European Union to refer to mineral wool fibers, it is also the terminology used in the classification entries for these materials in Regulation (EC) No 1272/2008 classification, labelling and packaging of substances and mixtures as the term synthetic vitreous fibers (SVF) is also used in literature and other jurisdictions to refer to mineral wool fibers.. Glass and stone wool fibers with different (high- and low-) solubility profiles were tested in closed-loop configuration using a sodium/potassium phosphate buffer solution or an acetate buffer, respectively. Results confirm a need to operate in diluted conditions to avoid silicon saturation in the simulant solution and suppression of fiber dissolution. A clear fiber-to-fiber differentiation with good cell-to-cell reproducibility was achieved. These findings support the continued development of a USP-4 protocol for MMVF in vitro acellular testing. • We report the successful evaluation of a USP-4 system to measuring the dissolution profiles of MMVF. • Clear differentiation between low- and high-solubility glass and stone wool fibers was observed • Results support the continued development of USP-4 protocols for MMVF in vitro dissolution rate measurements. [ABSTRACT FROM AUTHOR]

Published

2023

50. Organic Removal in the Water Body as the Effect of Mineral Wool Installation.

Author

Fathuna, Inat Shani, Soewondo, Prayatni, Prayogo, Wisnu, and Awfa, Dion

Subjects

BODIES of water, MINERAL wool, CHEMICAL kinetics, STANDARD deviations

Abstract

In previous studies, the use of mineral wools as an onsite-supporting media in water bodies showed satisfactory results in removing organic pollutants. However, the analytical method chosen is still very conventional. This study aimed to model the removal of organic pollutants represented by the COD value to determine the mineral performance. The data used in this study included field scale data using two types of mineral wools, namely type I (density 80 kg/m3 and water retention 95%) and type II (density 120 kg/m3 and water retention 92%). There are form variations of mineral wool namely cubes and blocks on each type, which are placed in segments 2, 4, 8, and 9, respectively, on the Cikapayang River. The modeling results show that the most optimal type of mineral wool to remove COD is type II mineral wool-cube form at segment 4 using the first order kinetics equation. The reaction coefficient (k) obtained is 0.5378/s, standard deviation value is 14.532 mg/L COD, and the coefficient of determination is 0.1025. The kinetics value of the reaction removal and equations obtained were used to perform modeling in Matlab R2020b application to determine the dimensions of the mineral wool required to remove pollutants. [ABSTRACT FROM AUTHOR]

Published

2023