Matías Renato Castro Castilloa, Jaime Xavier Nieto-Cardenasa, Paúl Illescas-Cárdenasa, Pilar Roxana Naspud Uruchimaa
aAcademic Unit of Engineering, Industry, and Construction, Universidad Católica de Cuenca. Cuenca, Ecuador, 010101.
Corresponding author: jxnietoc@ucacue.edu.ec
Vol. 04, Issue 01 (2025): July ISSN-e 2953-6634 ISSN Print: 3073-1526 Submitted: June 17, 2025 Revised: June 26, 2025 Accepted: July 12, 2025 Castro Castillo, M. R., Nieto-Cárdenas, J. X., Illescas-Cárdenas, P., & Naspud Uruchima, P. R. (2025). Desempeño mecánico de morteros reforzados con fibras de acero. EASI: Ingeniería Y Ciencias Aplicadas En La Industria, 4(1), 42–51. https://doi.org/10.53591/easi.v4i1.2410 Articles in journal repositories are freely open in digital form. Authors can reproduce and distribute the work on any non-commercial site and grant the journal the right of first publication with the work simultaneously licensed under a CC BY-NC-ND 4.0.
This article focuses on the evaluation of the resistance of mortars to indirect tension and compression, simple and reinforced, with different percentages of steel fiber. The aim is to find resistant and economical solutions to reinforce informal housing, through the use of plaster that improves the general characteristics of a masonry. Masonry constructed in an informal or artisanal manner has a high degree of structural vulnerability. First, the indirect tensile strength and displacements supported by simple and reinforced mortars are compared, where it is observed that reinforced mortars offer greater strength and deformation capacity as a function of the percentage of fiber. Then, the compressive strength is compared, where the reinforced mortars also show adequate results. In terms of economics, the reinforced mortar presents disadvantages due to the cost of the fibers; in the percentages studied in this article (10, 15, 20 and 25%), the use of reinforced mortars for informal housing is not so attractive; it is recommended to develop similar investigations with different percentages of fiber.
Este artículo se centra en la evaluación de la resistencia a la tracción y compresión indirectas de morteros, simples y reforzados, con diferentes porcentajes de fibra de acero. El objetivo es encontrar soluciones resistentes y económicas para reforzar viviendas informales, mediante el uso de revoque que mejore las características generales de la mampostería. La mampostería construida de manera informal o artesanal presenta un alto grado de vulnerabilidad estructural. En primer lugar, se compara la resistencia a la tracción indirecta y los desplazamientos soportados por morteros simples y reforzados, donde se observa que los morteros reforzados ofrecen mayor resistencia y capacidad de deformación en función del porcentaje de fibra. Posteriormente, se compara la resistencia a la compresión, donde los morteros reforzados también muestran resultados adecuados. En términos económicos, el mortero reforzado presenta desventajas debido al costo de las fibras; en los porcentajes estudiados en este artículo (10, 15, 20 y 25%), el uso de morteros reforzados para viviendas informales no resulta tan atractivo; se recomienda desarrollar investigaciones similares con diferentes porcentajes de fibra.
Construction is a widespread activity globally. In Latin America, approximately 50% of construction is carried out informally, without the supervision of a qualified professional (El Comercio / IG-EPN, 2011). One of the main characteristics of this type of practice is the limited adherence to building codes and minimum construction standards (Vergara-Perucich et al., 2022). These structures often exhibit significant deficiencies, especially in the face of seismic events or extreme weather conditions (Samaniego, 2020). One potential solution involves reinforcing existing masonry to effectively increase the strength, durability, and stability of such structures, thereby ensuring the safety of occupants (Gonzalez, 2015).
A key component of non-structural masonry is mortar, which consists of a mixture of cement, fine aggregate, water, and additives. Due to its versatility, mortar is commonly used for block bonding, coating, and plastering walls (Quirós, 2018). In an effort to improve the physical and mechanical properties of this material, researchers have explored the incorporation of fibers and additives into mortar mixes. Among the different types of fibers, steel fibers stand out due to their excellent mechanical properties (Aguirre, 2021).
The use of fibers in masonry mortars has been documented since the 20th century. Graham introduced them to enhance strength and durability, and in 1920, Griffith published the first scientific study on the use of steel fibers in mortars (Bustos García, 2018). Steel fibers act as reinforcement within the cementitious matrix, improving tensile and flexural performance and thereby reducing cracks and fissures under load (Marcalíková et al., 2019). These fibers are known to increase both load-bearing capacity and durability, making them an optimal option for constructions with low initial strength (Nam, J.W.; Kim, S.M.; Park, S.H.; Han, 2018).
Recent studies on non-structural masonry reinforced with metallic fibers have shown promising results. For instance, Dawood & Ramli (2010), Guo et al. (2024), and Nian et al. (2024) investigated improvements in impact resistance and crack control in cementitious materials through the incorporation of steel fibers at various scales. He (2023) characterized the uniaxial tensile behavior of high-performance concrete enhanced with nano-concrete fibers. Another example is the reported increase in stiffness—2.4 times higher than mortars reinforced with welded wire mesh and 3.8 times higher than unreinforced walls. Furthermore, mortars reinforced with steel fibers exhibited a 67% increase in strength compared to unreinforced ones, and a 6.5% improvement over mortars reinforced only with welded mesh (Nieto-Cárdenas et al., 2023).
Other studies, such as those by Hidayat et al. (2021) and Li et al. (2011), analyzed variations in compressive and flexural behavior in fiber-reinforced mortars. At early ages, fibers also help control cracking during the hardening process, as demonstrated by Kang et al. (2024). Similarly, Nian et al. (2024) examined the influence of fibers in asphalt mixtures. Shen et al. (2022) and collaborators developed a mathematical model to predict crack formation in beams reinforced with steel fibers and BFRP bars. In addition, Pan & Ma (2017) and Younis et al. (2021) analyzed the impact resistance of concrete with metallic fibers. In the context of fatigue performance in high-strength concrete beams, Zhang et al. (2025) observed superior behavior in elements reinforced with steel fibers.
In general, whether in concrete, asphalt, or mortar (Carrillo et al., 2020; Hidayat et al., 2021b; Li et al., 2011b; Shi et al., 2021), the incorporation of fibers demonstrates considerable potential to enhance mechanical properties. This makes fiber reinforcement a viable solution for structurally improving informal housing.
This study presents two comparative analyses: first, it examines the mechanical properties (force–displacement behavior) of plain mortar and mortar reinforced with metallic fiber (DRAMIX 3D) at four different fiber contents by weight of cement: 10%, 15%, 20%, and 25% in indirect tension, and 10%, 15%, and 20% in compression. Second, it compares the strength and cost between plain mortar and fiber-reinforced mortars. The objective is to determine the optimal steel fiber content for application in the plastering of informal housing, where walls typically lack protective coatings. This reinforcement aims to prevent masonry block detachment during seismic events, thereby improving the structural integrity of dwellings and the safety of their occupants.
In summary, the use of steel fibers in masonry mortar—particularly for informal housing—offers an accessible solution for enhancing structural strength, reducing cracking, and increasing durability. This contributes to improved safety for residents in the face of seismic and other adverse events.
The experimental study involved testing a commonly used mortar with a sand-to-cement ratio of 3:1. This mortar was evaluated both in its plain state and with steel fiber reinforcement at 10%, 15%, 20%, and 25% by weight of cement in the mix.
The preparation process, applicable standards, and theoretical foundations are outlined as follows:
Prior to mortar mixing, tests were conducted to determine the granulometry, density, and moisture content of the fine aggregate, as well as the density of the cement.
The granulometric analysis of fine aggregate was performed according to ASTM C136 (ASTM International, 2015).
The density of the fine aggregate was determined following ASTM C128 (ASTM International, 2023).
The density of the cement was calculated in accordance with ASTM C188 (ASTM International, 2023).
The 3:1 mortar mix design is based on Sánchez (2000), using a volumetric proportioning method, which closely replicates mixing practices in informal construction.
The mixing of mortar for cylindrical and cubic specimens was carried out manually to emulate methods used in informal housing construction.
A total of 7 cylinders and 6 cubes were prepared for each mortar type to perform indirect tensile and axial compression tests.
Indirect tensile tests were conducted according to ASTM C496 (ASTM International, 2016). Cylindrical specimens with a diameter of 10 cm and a height of 20 cm were tested using a loading rate of 0.234 kgf/cm²/s (ASTM International, 2016).
Compression tests were performed following ASTM C109 (ASTM International, 2015). Cubic specimens with 50 mm edge length were tested using a loading rate of 2.5 kgf/cm²/s (ASTM International, 2015).
The materials and equipment used in this research are listed below:
Fine aggregate sourced from the canton of Santa Isabel, Azuay Province, Ecuador.
Type GU cement (Guapán, n.d.).
DRAMIX 3D steel fibers from the company Ideal Alambrec-Bekaert (Ltd., 2017).
Cubic and cylindrical molds for casting mortar specimens.
Shimadzu Concrete 2000x series hydraulic press for indirect tensile and compression tests.
Minor tools such as scales, shovels, wheelbarrows, compaction rods, rubber hammers, and other general tools.
Le Chatelier flask and Abrams cone.
Figure 1. Materials used in mortar production.
Figure 2. Tools used for the experimental tests.
Table 1. Designation and Coding of the Specimens.
| Code | Description |
|---|---|
| TI.MS | Cylindrical specimen of plain mortar |
| TI.M-10 | Cylindrical specimen of mortar with 10% fiber |
| TI.M-15 | Cylindrical specimen of mortar with 15% fiber |
| TI.M-20 | Cylindrical specimen of mortar with 20% fiber |
| TI.M-25 | Cylindrical specimen of mortar with 25% fiber |
| MS | Cubic specimen of plain mortar |
| M-10 | Cubic specimen of mortar with 10% fiber |
| M-15 | Cubic specimen of mortar with 15% fiber |
| M-20 | Cubic specimen of mortar with 20% fiber |
Figure 3. Manual mixing process of the mortar.
Figure 4. Casting and demolding of mortar specimens.
The results of the experimental investigation are presented as follows:
The fineness modulus of the sand was determined to be 2.79, which complies with the ASTM C136 standard [12], falling within the acceptable range of 2.30 to 3.10.
The density of the cement, obtained using the Le Chatelier flask in accordance with ASTM C188 [14], was 2.81 g/cm³.
The relative density of the sand was found to be 2.30, calculated using the pycnometer method in accordance with ASTM C128 [13].
The force–deformation curves and compressive strength results presented in the following graphs illustrate the mechanical response of the specimens after testing using a hydraulic press, through indirect tensile and compressive strength tests.
Indirect tensile strength results of mortars:
The graphs in
Figure 5. Force–displacement curves from indirect tensile tests.
The graphs in
Figure 6. Force–displacement curves from uniaxial compression tests.
Figure 7. Summary force–displacement curves from indirect tensile and uniaxial compression tests.
After analyzing the compression and indirect tensile test curves for the different mortar types, the following observations can be made:
The mortar specimen that withstood the highest indirect tensile load was the one with 25% fiber content, supporting a load of 50.36 kN.
The specimen with the highest compressive strength corresponded to the mortar with 20% fiber content, reaching 7 MPa.
The greatest maximum displacement in the indirect tensile test was recorded in the 15% fiber specimen, with a displacement of 3.14 mm before failure.
In the compression tests, the plain mortar showed a very similar response to the mortars reinforced with 10% and 15% fiber, indicating that adding these percentages of fiber does not significantly improve compressive strength.
In the indirect tensile tests, the plain mortar displayed a clearly different response compared to any fiber-reinforced mortar, exhibiting an almost entirely elastic behavior, whereas fiber-reinforced mortars demonstrated post-peak resistance and increased energy absorption.
Strength vs. Cost Analysis per Cubic Meter of Mortar (Uninstalled):
A unit price analysis was performed considering current market costs of the materials in the local context:
Cement: $0.16 per kg
Steel fiber: $4.00 per kg
Sand: $0.01 per kg
Water: $0.57 per m³
Labor: $3.50 per hour
Table 2. Summary Table of Strength–Cost Comparison.
| Mortar | Compressive Strength (MPa) | Indirect Tensile Strength (kN) | Cost per m³ (USD) |
|---|---|---|---|
| Simple | 7,20 | 15,01 | 110,90 |
| 10% fiber | 8,70 | 20.46 | 335,54 |
| 15%fiber | 5,60 | 43,55 | 447,86 |
| 20% fiber | 7,00 | 24,11 | 560,18 |
| 25% fiber | N/A | 50,36 | 672 |
The difference in cost per cubic meter of mortar is mainly attributed to the amount of fiber used, as the unit price of steel fibers is relatively high and they are currently not easily available in the local market.
This research demonstrates the increase in mortar strength resulting from the inclusion of steel fibers in the mix. The key findings from the results are summarized below:
Workability is severely compromised, making the mixing and application process difficult.
Cost is substantially increased—this mortar is 6.02 times more expensive than plain mortar due to the high price of steel fiber, which is 21 times more costly than cement per kilogram.
Within the range of fiber contents studied, this type of mortar is not recommended for informal housing applications, mainly due to its high cost and poor workability. It is suggested that future studies evaluate lower fiber percentages than those tested in this article.
The authors recommend further research to develop a future line of knowledge, particularly exploring the application of fiber-reinforced mortars in compression-loaded masonry prisms, to better understand their potential contribution to masonry wall performance.
The authors express their sincere gratitude to the family of Engineer Matías Castro, who kindly provided valuable information that made it possible to complete this work. Engineer Castro sadly passed away a few weeks after finishing his degree project. We also thank the laboratories of the Universidad Católica de Cuenca for their support and collaboration during the experimental phase of this research.