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Peer-Review Record

Ferrocement, Carbon, and Polypropylene Fibers for Strengthening Masonry Shear Walls

Materials 2023, 16(13), 4597; https://doi.org/10.3390/ma16134597

by Enea Mustafaraj¹

, Marco Corradi^2,*

, Yavuz Yardim³

, Erion Luga¹ and Muhammed Yasin Codur¹

Reviewer 1:

Eryu Zhu

Reviewer 2:

Angelo Aloisio

Reviewer 3:

Daniel Ferrández

Materials 2023, 16(13), 4597; https://doi.org/10.3390/ma16134597

Submission received: 4 June 2023 / Revised: 21 June 2023 / Accepted: 22 June 2023 / Published: 26 June 2023

(This article belongs to the Special Issue Repair, Reinforcement, Conservation of Existing Building Stock: Materials, Methods and Assessment)

Round 1

Reviewer 1 Report

1.In Figure 2-a, it can be seen that the threaded bolts are not evenly arranged, does it affect the test results?

2. Part of the picture number is wrong, as shown in Figure 90, 101, 125 and 136;

3.From Section 4 of the article, it can be seen that the test has been simulated in advance, but why there is no simulation effect diagram, especially the corresponding cracking simulation diagram. Is the conclusion given too simple? The simulation effect is not ideal, so what is the meaning of this part?

4.In Figure 14, the URM analysis is "the average shear strength of the URM panels was 0.153 MPa, with a maximum of 0.177 MPa reached for W1 and a minimum of 0.129 MPa for W2.", but the maximum shear stress of the URM specimen in Figure 14 shows W3, and the maximum test load in Table 6 is also W3, which is inconsistent with the description, and needs to be verified

5.It can be seen from Figure 14 that the results of the same group of specimens show a certain degree of discreteness, but the results of different groups of specimens have certain regularity. Among the three specimens in the same group, the results of two specimens show consistency, but there is always one showing a large deviation from the others. Are there other factors in the test?

6. In Figure 14, W-8 value reaches its peak and remains stable. Is it wrong?

7.The analysis of the reinforcement mechanism is still lacking, and the feasibility of reinforcement is only given from the comparison of test phenomena and data levels, and the depth of content is insufficient.

The English writing level of the article is relatively high, which can well display the viewpoints of the paper, and the layout is relatively reasonable.

Author Response

1.In Figure 2-a, it can be seen that the threaded bolts are not evenly arranged, does it affect the test results?

RESPONSE: The arrangement of the bolts is made in a certain way that they are anchored in the bricks. Overall, the bolts will ensure the connection of the mesh in the total area of the wall panel. As long as there is a sufficient number of them (12 anchors per square meter) all over the reinforced area, it will not have any effect on the performance.

Part of the picture number is wrong, as shown in Figure 90, 101, 125 and 136;

RESPONSE: Corrected.

RESPONSE: As we know, masonry is a non-homogeneous anisotropic material whose real behavior is very difficult to be predicted. The FE simulation aimed at analyzing the behavior, and as it was observed from the results, the shear-stress strain behavior was very similar in terms of deformation capacity and the shear strength,

RESPONSE: Thank you for pointing this out. It was a typo. The value for W1 is corrected to 0.117 instead of 0.177 MPa. At the same time, also the ratios of FC vs. URM, PP vs. URM and CFRP vs. URM are also updated.

RESPONSE: During the experimental campaign, we tried to keep all the input parameters (construction materials, mortar mix, using the same mason worker) as well as the testing conditions the same. The variation in the results is due to the non-homogeneity and anisotropy of masonry. Nevertheless, the maximum variance is seen in URM (c.o.v= 0.13), then in FC (c.o.v = 0.12), PP (c.o.v = 0.1) and CFRP (c.o.v = 0.06)

In Figure 14, W-8 value reaches its peak and remains stable. Is it wrong?

RESPONSE: W8 was reinforced with Polyproplyene. The panel managed to keep the ultimate load constant for a certain time, then it failed. Considering its deformation capacity, slightly less than 0.003 mm/mm deformed more than W9 but less than W7.

The analysis of the reinforcement mechanism is still lacking, and the feasibility of reinforcement is only given from the comparison of test phenomena and data levels, and the depth of content is insufficient.

RESPONSE: Thank you for this comment. Analysis was elaborated more and reflected in the text

Reviewer 2 Report

The paper is well-written and shows promise for publication. However, there are several major aspects that need to be addressed before it can be considered for publication.

Firstly, the introduction needs to clearly identify the gap in knowledge that this paper fills. It should be organized as follows: provide a general overview of the problem, discuss what has already been done in the field, highlight the aspects that are lacking in the existing literature, and clearly explain how the authors' work addresses these gaps.

Additionally, the reference list is missing several important contributions related to the experimental side of masonry walls, both with and without reinforcement. The following references should be included:

Khan, N. A., Aloisio, A., Monti, G., Nuti, C., & Briseghella, B. (2023). Experimental characterization and empirical strength prediction of Pakistani brick masonry walls. Journal of Building Engineering, 71, 106451.

Gonen, S., Pulatsu, B., Lourenço, P. B., Lemos, J. V., Tuncay, K., & Erduran, E. (2023). Analysis and prediction of masonry wallette strength under combined compression-bending via stochastic computational modeling. Engineering Structures, 278, 115492.

There is an issue with the formatting in line 155, which should be corrected.

To provide clarity on the tests conducted, it would be beneficial to create a table that lists all the tests, their labels, and the variables that have been varied. This table should also distinguish between different specimens used in the study.

The comparison between the experimental and numerical results could be improved by creating a table that reports the numerical values alongside the corresponding experimental values for initial stiffness, secondary stiffness, capacity, and ductility. Additionally, the table should include the relative error between the two sets of values.

Lastly, the language and spelling in the paper need improvement as there are several typos present. Careful proofreading and editing should be conducted to enhance the overall quality of the manuscript.

Author Response

Firstly, the authors would like to thank the reviewers for their valuable comments and suggestions. We believe that thanks to these suggestions, the quality of the manuscript is considerably improved.

Reviewer #2

The paper is well-written and shows promise for publication. However, there are several major aspects that need to be addressed before it can be considered for publication.

Firstly, the introduction needs to clearly identify the gap in knowledge that this paper fills. It should be organized as follows: provide a general overview of the problem, discuss what has already been done in the field, highlight the aspects that are lacking in the existing literature, and clearly explain how the authors' work addresses these gaps.
Additionally, the reference list is missing several important contributions related to the experimental side of masonry walls, both with and without reinforcement. The following references should be included:

RESPONSE: these relevant citations have been added to the manuscript and the objective of this study is added in the Introduction.

There is an issue with the formatting in line 155, which should be corrected.

RESPONSE: Corrected.

To provide clarity on the tests conducted, it would be beneficial to create a table that lists all the tests, their labels, and the variables that have been varied. This table should also distinguish between different specimens used in the study.

RESPONSE: The text has been improved to better illustrate the test program “The main aim of the testing campaign was to investigate various strengthening methods that can be used to improve the lateral load capacity of the masonry shear walls. The experimental campaign was designed in such a way as to compare the effectiveness of polypropylene fibers, ferrocement jacketing, and carbon fibers used as strengthening techniques. The experimental campaign consisted of a total of 12 wall specimens that were tested in diagonal compression. Nominal wall dimensions were 1200x1200x250 mm (height (h) x width (w) x thickness (t)). Each retrofit has been applied to 3 wall panels (total 9 wall panels for the 3 retrofitting methods investigated). 3 wall panels were left unreinforced (control specimens) to study the effectiveness of the retrofitting method by comparison.”

The comparison between the experimental and numerical results could be improved by creating a table that reports the numerical values alongside the corresponding experimental values for initial stiffness, secondary stiffness, capacity, and ductility. Additionally, the table should include the relative error between the two sets of values.

RESPONSE: we have completely revised by adding text and analysis to the section where numerical results are compared with experimental ones.

RESPONSE: Corrected. Thank you

Reviewer 3 Report

The authors present an interesting research work that may be useful for technicians and professionals in the construction sector. Full-scale walls are tested, which gives a very approximate idea of the mechanical behaviour of these construction systems with and without reinforcement. The article is appropriate for this journal.

However, some comments need to be resolved before publication:

Line 15: "This paper..." suggested to be changed to "This research..."

Line 34, add reference to support that statement.

Line 72, 150 x 150 mm

The objective is unclear and diffuse. Clearly state the objective of the research at the end of the introduction.

Page 5 has a page break

Line 155 correct, there appears to be a figure that has been moved.

Figure 4 is repeated

Section 3 and 4 should be merged with section 2.Materials and Methods.

Section 4.1. is well known, perhaps it could be schematised.

Line 336 and 338, cannot be Table 1, should be Table 5.

Line 379, Correct Figure 101) and the end of the sentence.

There is no final discussion of the numerical results and at no point are the results compared with other research. This section should be corrected.

Line 490. Figure 136

The limitations found in this research should be included at the end of the conclusions.

-The article is generally well written.

Author Response

Reviewer #3

However, some comments need to be resolved before publication:

Line 15: "This paper..." suggested to be changed to "This research..."

RESPONSE: Corrected. Thank you

Line 34, add reference to support that statement.

RESPONSE: Corrected. A reference has been added here to support this.

Line 72, 150 x 150 mm

RESPONSE: Corrected. Thank you

The objective is unclear and diffuse. Clearly state the objective of the research at the end of the introduction.

RESPONSE: Thank you for this question. The following paragraph was added: “The objective of this research is to study low-cost solutions (ferrocement and polypropylene fibers) rarely adopted for structural interventions in seismic prone areas and compare them with a more “advanced” method, more expensive and less “environ-mentally friendly” (CFRP).”

Page 5 has a page break