TY  - CHAP
AU  - Martinović, Sanja
AU  - Vlahović, Milica
AU  - Boljanac, Tamara
AU  - Matović, Branko
AU  - Volkov-Husović, Tatjana
PY  - 2014
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2572
AB  - Lifetime prediction for construction material is essential and very often crucial for determination of impact on material application and service. Many models based on different parameters were used to monitor materials behavior subjected to different extreme conditions such as thermal shock and erosive wear. In this chapter, image analysis for lifetime prediction of refractory concrete, more precisely low cement high alumina castable, during the thermal shock and cavitation erosion was studied and discussed. Generally, analyzed material has the properties that depend on sintering temperature but usually is a material with very high strength, density, hardness, and good thermal stability resistance. Usage of image analysis for lifetime prediction of refractory concrete during the thermal shock and cavitation erosion were the goals of this study. Thermal stability was investigated using most common experimental method, water quench test. Destruction of samples during the testing was monitored by image analysis. Results obtained from the image analysis of samples surface and bulk give proof that the level of degradation induced by extreme conditions can be monitored by this way. Values of degradation level were used for lifetime modeling expressed as strength degradation, and correlated to the experimental values. Based on the models for strength degradation using degradation level as variable, model for lifetime was proposed. Similar approach was applied in case of monitoring the degradation level caused by cavitation erosion experiments. The fluid dynamic system of the experimental methodology used to produce ultrasonic erosive wear. Mass loss and level of material degradation were measured before and during the experiment. Level of degradation, that is average erosion area were monitored by using Image Pro Plus program for image analysis. Obtained results showed that after 180 minutes sample exhibited excellent erosion resistance compared to metallic and ceramic samples. Level of surface degradation did not overcome 8 % compared to the original surface.
T2  - Advances in Image Analysis Research
T1  - Implementation of image analysis research on refractory concrete lifetime prediction for thermal stability and cavitation erosion testing
EP  - 186
SP  - 171
UR  - https://hdl.handle.net/21.15107/rcub_technorep_2572
ER  - 

@inbook{
author = "Martinović, Sanja and Vlahović, Milica and Boljanac, Tamara and Matović, Branko and Volkov-Husović, Tatjana",
year = "2014",
abstract = "Lifetime prediction for construction material is essential and very often crucial for determination of impact on material application and service. Many models based on different parameters were used to monitor materials behavior subjected to different extreme conditions such as thermal shock and erosive wear. In this chapter, image analysis for lifetime prediction of refractory concrete, more precisely low cement high alumina castable, during the thermal shock and cavitation erosion was studied and discussed. Generally, analyzed material has the properties that depend on sintering temperature but usually is a material with very high strength, density, hardness, and good thermal stability resistance. Usage of image analysis for lifetime prediction of refractory concrete during the thermal shock and cavitation erosion were the goals of this study. Thermal stability was investigated using most common experimental method, water quench test. Destruction of samples during the testing was monitored by image analysis. Results obtained from the image analysis of samples surface and bulk give proof that the level of degradation induced by extreme conditions can be monitored by this way. Values of degradation level were used for lifetime modeling expressed as strength degradation, and correlated to the experimental values. Based on the models for strength degradation using degradation level as variable, model for lifetime was proposed. Similar approach was applied in case of monitoring the degradation level caused by cavitation erosion experiments. The fluid dynamic system of the experimental methodology used to produce ultrasonic erosive wear. Mass loss and level of material degradation were measured before and during the experiment. Level of degradation, that is average erosion area were monitored by using Image Pro Plus program for image analysis. Obtained results showed that after 180 minutes sample exhibited excellent erosion resistance compared to metallic and ceramic samples. Level of surface degradation did not overcome 8 % compared to the original surface.",
journal = "Advances in Image Analysis Research",
booktitle = "Implementation of image analysis research on refractory concrete lifetime prediction for thermal stability and cavitation erosion testing",
pages = "186-171",
url = "https://hdl.handle.net/21.15107/rcub_technorep_2572"
}

Martinović, S., Vlahović, M., Boljanac, T., Matović, B.,& Volkov-Husović, T.. (2014). Implementation of image analysis research on refractory concrete lifetime prediction for thermal stability and cavitation erosion testing. in Advances in Image Analysis Research, 171-186.
https://hdl.handle.net/21.15107/rcub_technorep_2572

Martinović S, Vlahović M, Boljanac T, Matović B, Volkov-Husović T. Implementation of image analysis research on refractory concrete lifetime prediction for thermal stability and cavitation erosion testing. in Advances in Image Analysis Research. 2014;:171-186.
https://hdl.handle.net/21.15107/rcub_technorep_2572 .

Martinović, Sanja, Vlahović, Milica, Boljanac, Tamara, Matović, Branko, Volkov-Husović, Tatjana, "Implementation of image analysis research on refractory concrete lifetime prediction for thermal stability and cavitation erosion testing" in Advances in Image Analysis Research (2014):171-186,
https://hdl.handle.net/21.15107/rcub_technorep_2572 .

TY  - CHAP
AU  - Vlahović, Milica
AU  - Martinović, Sanja
AU  - Jovanić, Predrag
AU  - Boljanac, Tamara
AU  - Volkov-Husović, Tatjana
PY  - 2014
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2569
AB  - The degradation of concrete structures, which progresses as time passes, is caused by external factors such as chemical, physical and mechanical interferences. In the case of chemical deterioration, various ions penetrate from the surface and then permeate into the concrete. Concrete structures are more or less porous materials, which have pores with a range of diameters. These pores have a detrimental influence on the strength of concrete and on the durability because they become permeation paths for other deterioration factors. Degradation of concrete structures often results in initiation and propagation of micro-cracks and other micro-defects. Since the presence of micro-cracks can significantly influence the mechanical properties of concrete, detection and control of micro-cracks is an essential issue for its durability. The prediction of material macroscopic properties requires a method capable of quantifying the material microstructural characteristics. Image analysis of the sample surface destruction is an important non-destructive method for assessing damage of the materials. Due to image analysis, more systematic and more accurate measurements have become possible. Therefore, more objective characterization of concrete structures from the aspect of material properties is provided. Evaluation of various concrete properties, as well as the effect of external influences on the microstructure of concrete, can be investigated using these non-destructive methodologies. The objective of the current study is focused on the quantifying surface cracks in concrete structures by using image analysis technique. In this chapter, application of image analysis in monitoring the level of surface destruction of sulfur concrete and Portland cement concrete subjected to corrosion conditions was presented. Macro- scale image analysis was realized with taking into account the total surface of the samples in order to monitor damage distribution at the surface. Micro- scale image analysis was applied to the specific areas of the sample surface, detected by the macro- scale image analysis as potential critical areas for further deterioration. Based on the image analysis results, the model for prediction of mechanical strength degradation was given. Mechanical strength measuring of the concrete samples was realized using classical, destructive testing method according to the standard. Agreement between calculated and experimental mechanical strength values confirmed that the proposed model was acceptable. The quantitative nature of this data and its regular collection can promote the establishment of deterioration criteria through the determination of correlation between deterioration factors and damage within concrete structures. In this context, this study constitutes an important contribution to a better understanding of image analysis, and how such tools can be used to assist in the assessment of the condition of concrete structures in order to provide more reliable concrete monitoring.
T2  - Advances in Image Analysis Research
T1  - Image analysis technique for evaluating damage evolution and predicting mechanical strength of concrete structures under corrosion conditions
EP  - 169
SP  - 147
UR  - https://hdl.handle.net/21.15107/rcub_technorep_2569
ER  - 

@inbook{
author = "Vlahović, Milica and Martinović, Sanja and Jovanić, Predrag and Boljanac, Tamara and Volkov-Husović, Tatjana",
year = "2014",
abstract = "The degradation of concrete structures, which progresses as time passes, is caused by external factors such as chemical, physical and mechanical interferences. In the case of chemical deterioration, various ions penetrate from the surface and then permeate into the concrete. Concrete structures are more or less porous materials, which have pores with a range of diameters. These pores have a detrimental influence on the strength of concrete and on the durability because they become permeation paths for other deterioration factors. Degradation of concrete structures often results in initiation and propagation of micro-cracks and other micro-defects. Since the presence of micro-cracks can significantly influence the mechanical properties of concrete, detection and control of micro-cracks is an essential issue for its durability. The prediction of material macroscopic properties requires a method capable of quantifying the material microstructural characteristics. Image analysis of the sample surface destruction is an important non-destructive method for assessing damage of the materials. Due to image analysis, more systematic and more accurate measurements have become possible. Therefore, more objective characterization of concrete structures from the aspect of material properties is provided. Evaluation of various concrete properties, as well as the effect of external influences on the microstructure of concrete, can be investigated using these non-destructive methodologies. The objective of the current study is focused on the quantifying surface cracks in concrete structures by using image analysis technique. In this chapter, application of image analysis in monitoring the level of surface destruction of sulfur concrete and Portland cement concrete subjected to corrosion conditions was presented. Macro- scale image analysis was realized with taking into account the total surface of the samples in order to monitor damage distribution at the surface. Micro- scale image analysis was applied to the specific areas of the sample surface, detected by the macro- scale image analysis as potential critical areas for further deterioration. Based on the image analysis results, the model for prediction of mechanical strength degradation was given. Mechanical strength measuring of the concrete samples was realized using classical, destructive testing method according to the standard. Agreement between calculated and experimental mechanical strength values confirmed that the proposed model was acceptable. The quantitative nature of this data and its regular collection can promote the establishment of deterioration criteria through the determination of correlation between deterioration factors and damage within concrete structures. In this context, this study constitutes an important contribution to a better understanding of image analysis, and how such tools can be used to assist in the assessment of the condition of concrete structures in order to provide more reliable concrete monitoring.",
journal = "Advances in Image Analysis Research",
booktitle = "Image analysis technique for evaluating damage evolution and predicting mechanical strength of concrete structures under corrosion conditions",
pages = "169-147",
url = "https://hdl.handle.net/21.15107/rcub_technorep_2569"
}

Vlahović, M., Martinović, S., Jovanić, P., Boljanac, T.,& Volkov-Husović, T.. (2014). Image analysis technique for evaluating damage evolution and predicting mechanical strength of concrete structures under corrosion conditions. in Advances in Image Analysis Research, 147-169.
https://hdl.handle.net/21.15107/rcub_technorep_2569

Vlahović M, Martinović S, Jovanić P, Boljanac T, Volkov-Husović T. Image analysis technique for evaluating damage evolution and predicting mechanical strength of concrete structures under corrosion conditions. in Advances in Image Analysis Research. 2014;:147-169.
https://hdl.handle.net/21.15107/rcub_technorep_2569 .

Vlahović, Milica, Martinović, Sanja, Jovanić, Predrag, Boljanac, Tamara, Volkov-Husović, Tatjana, "Image analysis technique for evaluating damage evolution and predicting mechanical strength of concrete structures under corrosion conditions" in Advances in Image Analysis Research (2014):147-169,
https://hdl.handle.net/21.15107/rcub_technorep_2569 .

TY  - JOUR
AU  - Martinović, Sanja
AU  - Vlahović, Milica
AU  - Boljanac, Tamara
AU  - Majstorović, Jelena
AU  - Volkov-Husović, Tatjana
PY  - 2014
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2837
AB  - The purpose of this study was to investigate behavior and degradation level of refractory concrete sintered at different temperatures during the thermal stability testing. Alumina based low cement castable was synthesized, cured, and then sintered at 1100, 1300, and 1600 degrees C with dwell time of 3 h. Prepared samples were subjected to the water quench test. Behavior of the refractory concrete and determination of surface and internal degradation level during the testing were monitored by ultrasonic measurements and image analysis. Overall material degradation was determined by measuring the strength degradation of samples using the standard laboratory procedure. The samples sintered at 1300 degrees C showed the best behavior under thermal shock, since they withstood 110 cycles of water quench without breaking. It was evident that during the thermal shock, surface and interior of the samples sintered at 1600 degrees C behave differently compared with those sintered at 1100 and 1300 degrees C.
PB  - Elsevier Sci Ltd, Oxford
T2  - Composites Part B-Engineering
T1  - Influence of sintering temperature on thermal shock behavior of low cement high alumina refractory concrete
EP  - 412
SP  - 400
VL  - 60
DO  - 10.1016/j.compositesb.2013.12.077
ER  - 

@article{
author = "Martinović, Sanja and Vlahović, Milica and Boljanac, Tamara and Majstorović, Jelena and Volkov-Husović, Tatjana",
year = "2014",
abstract = "The purpose of this study was to investigate behavior and degradation level of refractory concrete sintered at different temperatures during the thermal stability testing. Alumina based low cement castable was synthesized, cured, and then sintered at 1100, 1300, and 1600 degrees C with dwell time of 3 h. Prepared samples were subjected to the water quench test. Behavior of the refractory concrete and determination of surface and internal degradation level during the testing were monitored by ultrasonic measurements and image analysis. Overall material degradation was determined by measuring the strength degradation of samples using the standard laboratory procedure. The samples sintered at 1300 degrees C showed the best behavior under thermal shock, since they withstood 110 cycles of water quench without breaking. It was evident that during the thermal shock, surface and interior of the samples sintered at 1600 degrees C behave differently compared with those sintered at 1100 and 1300 degrees C.",
publisher = "Elsevier Sci Ltd, Oxford",
journal = "Composites Part B-Engineering",
title = "Influence of sintering temperature on thermal shock behavior of low cement high alumina refractory concrete",
pages = "412-400",
volume = "60",
doi = "10.1016/j.compositesb.2013.12.077"
}

Martinović, S., Vlahović, M., Boljanac, T., Majstorović, J.,& Volkov-Husović, T.. (2014). Influence of sintering temperature on thermal shock behavior of low cement high alumina refractory concrete. in Composites Part B-Engineering
Elsevier Sci Ltd, Oxford., 60, 400-412.
https://doi.org/10.1016/j.compositesb.2013.12.077

Martinović S, Vlahović M, Boljanac T, Majstorović J, Volkov-Husović T. Influence of sintering temperature on thermal shock behavior of low cement high alumina refractory concrete. in Composites Part B-Engineering. 2014;60:400-412.
doi:10.1016/j.compositesb.2013.12.077 .

Martinović, Sanja, Vlahović, Milica, Boljanac, Tamara, Majstorović, Jelena, Volkov-Husović, Tatjana, "Influence of sintering temperature on thermal shock behavior of low cement high alumina refractory concrete" in Composites Part B-Engineering, 60 (2014):400-412,
https://doi.org/10.1016/j.compositesb.2013.12.077 . .

TY  - JOUR
AU  - Martinović, Sanja
AU  - Vlahović, Milica
AU  - Boljanac, Tamara
AU  - Dojčinović, Marina
AU  - Volkov-Husović, Tatjana
PY  - 2013
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2513
AB  - The purpose of this study was to investigate possible application of refractory concrete in conditions of cavitation effect where the metal materials are usually applied. Also, influence of different sintering temperatures on cavitation resistance of refractory concrete was analyzed. As the refractory concrete, low cement castable was synthesized, cured, and then sintered at three different temperatures: 1100, 1300, and 1600 degrees C. Mass loss and surface degradation of investigated samples were monitored for 3 h during the exposure to the cavitation erosion. The results show that the samples sintered at 1100 degrees C are not suitable for application in conditions of cavitation since they were significantly destroyed only after 30 min of testing. On the other side, the samples sintered at 1300 and 1600 degrees C exhibited very good cavitation resistance, since they were stable during 360 min of cavitation testing with the damage level below 30% compared to the original surface.
PB  - Elsevier Sci Ltd, Oxford
T2  - Journal of the European Ceramic Society
T1  - Cavitation resistance of refractory concrete: Influence of sintering temperature
EP  - 14
IS  - 1
SP  - 7
VL  - 33
DO  - 10.1016/j.jeurceramsoc.2012.08.004
ER  - 

@article{
author = "Martinović, Sanja and Vlahović, Milica and Boljanac, Tamara and Dojčinović, Marina and Volkov-Husović, Tatjana",
year = "2013",
abstract = "The purpose of this study was to investigate possible application of refractory concrete in conditions of cavitation effect where the metal materials are usually applied. Also, influence of different sintering temperatures on cavitation resistance of refractory concrete was analyzed. As the refractory concrete, low cement castable was synthesized, cured, and then sintered at three different temperatures: 1100, 1300, and 1600 degrees C. Mass loss and surface degradation of investigated samples were monitored for 3 h during the exposure to the cavitation erosion. The results show that the samples sintered at 1100 degrees C are not suitable for application in conditions of cavitation since they were significantly destroyed only after 30 min of testing. On the other side, the samples sintered at 1300 and 1600 degrees C exhibited very good cavitation resistance, since they were stable during 360 min of cavitation testing with the damage level below 30% compared to the original surface.",
publisher = "Elsevier Sci Ltd, Oxford",
journal = "Journal of the European Ceramic Society",
title = "Cavitation resistance of refractory concrete: Influence of sintering temperature",
pages = "14-7",
number = "1",
volume = "33",
doi = "10.1016/j.jeurceramsoc.2012.08.004"
}

Martinović, S., Vlahović, M., Boljanac, T., Dojčinović, M.,& Volkov-Husović, T.. (2013). Cavitation resistance of refractory concrete: Influence of sintering temperature. in Journal of the European Ceramic Society
Elsevier Sci Ltd, Oxford., 33(1), 7-14.
https://doi.org/10.1016/j.jeurceramsoc.2012.08.004

Martinović S, Vlahović M, Boljanac T, Dojčinović M, Volkov-Husović T. Cavitation resistance of refractory concrete: Influence of sintering temperature. in Journal of the European Ceramic Society. 2013;33(1):7-14.
doi:10.1016/j.jeurceramsoc.2012.08.004 .

Martinović, Sanja, Vlahović, Milica, Boljanac, Tamara, Dojčinović, Marina, Volkov-Husović, Tatjana, "Cavitation resistance of refractory concrete: Influence of sintering temperature" in Journal of the European Ceramic Society, 33, no. 1 (2013):7-14,
https://doi.org/10.1016/j.jeurceramsoc.2012.08.004 . .

TY  - CHAP
AU  - Vlahović, Milica
AU  - Jovanić, Predrag
AU  - Martinović, Sanja
AU  - Boljanac, Tamara
AU  - Volkov-Husović, Tatjana
PY  - 2013
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2263
AB  - Sulfur- polymer composites are high performance thermoplastic materials made of mineral aggregate, filler, and modified sulfur binder, instead of cement and water as in ordinary Portland cement- based composites at temperatures above the hardening point of sulfur (120°C). Using sulfur to obtain modified sulfur binder is based on its physicochemical characteristics. According to our terminology, modified sulfur binder considers a mixture of elemental sulfur and modified sulfur- sulfur polymer. Contemporary experience all over the world shows that composite materials with modified sulfur binder instead of cement and water have significant chemical and physico- mechanical advantages comparing with Portland cement- based composites. Modern trends of obtaining materials with desired properties are based on combining ingredients with different properties in different proportions, as well as on the application of various manufacturing procedures and additional material processing. Having in mind that while in service use, all materials are exposed to divers external influences that provoke some type of response, the idea of this research was to change the quality of sulfur- polymer composite by imposed chemical stress. Since sulfur- polymer composites are relatively new building materials that can potentially replace conventional material made with Portland cement as a binder in many branches of construction, it was found plausible to choose Portland cement- based composite as a referent material. In order to quantify the changes in the material structure as its response to the specific imposed stimulus, the scanning electron microscopy (SEM) and energy dispersive X-ray analysis (EDX) were applied. According to the applied analyses on micro level, it can be concluded that the initial structure of sulfur- polymer composite was rearranged. As a macro level result material with better resistance to chemically imposed stress compared with the referent material was obtained.
T2  - New Developments in Polymer Composites Research
T1  - Influence of chemical stress on sulfur-polymer composite structure
EP  - 278
SP  - 257
UR  - https://hdl.handle.net/21.15107/rcub_technorep_2263
ER  - 

@inbook{
author = "Vlahović, Milica and Jovanić, Predrag and Martinović, Sanja and Boljanac, Tamara and Volkov-Husović, Tatjana",
year = "2013",
abstract = "Sulfur- polymer composites are high performance thermoplastic materials made of mineral aggregate, filler, and modified sulfur binder, instead of cement and water as in ordinary Portland cement- based composites at temperatures above the hardening point of sulfur (120°C). Using sulfur to obtain modified sulfur binder is based on its physicochemical characteristics. According to our terminology, modified sulfur binder considers a mixture of elemental sulfur and modified sulfur- sulfur polymer. Contemporary experience all over the world shows that composite materials with modified sulfur binder instead of cement and water have significant chemical and physico- mechanical advantages comparing with Portland cement- based composites. Modern trends of obtaining materials with desired properties are based on combining ingredients with different properties in different proportions, as well as on the application of various manufacturing procedures and additional material processing. Having in mind that while in service use, all materials are exposed to divers external influences that provoke some type of response, the idea of this research was to change the quality of sulfur- polymer composite by imposed chemical stress. Since sulfur- polymer composites are relatively new building materials that can potentially replace conventional material made with Portland cement as a binder in many branches of construction, it was found plausible to choose Portland cement- based composite as a referent material. In order to quantify the changes in the material structure as its response to the specific imposed stimulus, the scanning electron microscopy (SEM) and energy dispersive X-ray analysis (EDX) were applied. According to the applied analyses on micro level, it can be concluded that the initial structure of sulfur- polymer composite was rearranged. As a macro level result material with better resistance to chemically imposed stress compared with the referent material was obtained.",
journal = "New Developments in Polymer Composites Research",
booktitle = "Influence of chemical stress on sulfur-polymer composite structure",
pages = "278-257",
url = "https://hdl.handle.net/21.15107/rcub_technorep_2263"
}

Vlahović, M., Jovanić, P., Martinović, S., Boljanac, T.,& Volkov-Husović, T.. (2013). Influence of chemical stress on sulfur-polymer composite structure. in New Developments in Polymer Composites Research, 257-278.
https://hdl.handle.net/21.15107/rcub_technorep_2263

Vlahović M, Jovanić P, Martinović S, Boljanac T, Volkov-Husović T. Influence of chemical stress on sulfur-polymer composite structure. in New Developments in Polymer Composites Research. 2013;:257-278.
https://hdl.handle.net/21.15107/rcub_technorep_2263 .

Vlahović, Milica, Jovanić, Predrag, Martinović, Sanja, Boljanac, Tamara, Volkov-Husović, Tatjana, "Influence of chemical stress on sulfur-polymer composite structure" in New Developments in Polymer Composites Research (2013):257-278,
https://hdl.handle.net/21.15107/rcub_technorep_2263 .

TY  - JOUR
AU  - Vlahović, Milica M.
AU  - Jovanić, Predrag
AU  - Martinović, Sanja
AU  - Boljanac, Tamara
AU  - Volkov-Husović, Tatjana
PY  - 2013
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2494
AB  - In order to predict service life of the sulfur polymer composite, the samples were subjected to the induced destruction using 10% hydrochloric acid solution. Control specimens were prepared using Portland cement binder. Sulfur polymer composite showed limited mechanical strength and mass loss, while physico-mechanical properties of Portland cement composite regressed rapidly. The Image Pro Plus software was used for surface destruction monitoring. The simulations for composites were applied to the previously reported model for predicting the mechanical strength degradation during durability testing, based on the image analysis results. The results proved that the time gradient of structural change was useful for quantification of service life, therefore it can be accepted as a parameter that represents service life.
PB  - Elsevier Sci Ltd, Oxford
T2  - Composites Part B-Engineering
T1  - Quantitative evaluation of sulfur-polymer matrix composite quality
EP  - 466
IS  - 1
SP  - 458
VL  - 44
DO  - 10.1016/j.compositesb.2012.04.005
ER  - 

@article{
author = "Vlahović, Milica M. and Jovanić, Predrag and Martinović, Sanja and Boljanac, Tamara and Volkov-Husović, Tatjana",
year = "2013",
abstract = "In order to predict service life of the sulfur polymer composite, the samples were subjected to the induced destruction using 10% hydrochloric acid solution. Control specimens were prepared using Portland cement binder. Sulfur polymer composite showed limited mechanical strength and mass loss, while physico-mechanical properties of Portland cement composite regressed rapidly. The Image Pro Plus software was used for surface destruction monitoring. The simulations for composites were applied to the previously reported model for predicting the mechanical strength degradation during durability testing, based on the image analysis results. The results proved that the time gradient of structural change was useful for quantification of service life, therefore it can be accepted as a parameter that represents service life.",
publisher = "Elsevier Sci Ltd, Oxford",
journal = "Composites Part B-Engineering",
title = "Quantitative evaluation of sulfur-polymer matrix composite quality",
pages = "466-458",
number = "1",
volume = "44",
doi = "10.1016/j.compositesb.2012.04.005"
}

Vlahović, M. M., Jovanić, P., Martinović, S., Boljanac, T.,& Volkov-Husović, T.. (2013). Quantitative evaluation of sulfur-polymer matrix composite quality. in Composites Part B-Engineering
Elsevier Sci Ltd, Oxford., 44(1), 458-466.
https://doi.org/10.1016/j.compositesb.2012.04.005

Vlahović MM, Jovanić P, Martinović S, Boljanac T, Volkov-Husović T. Quantitative evaluation of sulfur-polymer matrix composite quality. in Composites Part B-Engineering. 2013;44(1):458-466.
doi:10.1016/j.compositesb.2012.04.005 .

Vlahović, Milica M., Jovanić, Predrag, Martinović, Sanja, Boljanac, Tamara, Volkov-Husović, Tatjana, "Quantitative evaluation of sulfur-polymer matrix composite quality" in Composites Part B-Engineering, 44, no. 1 (2013):458-466,
https://doi.org/10.1016/j.compositesb.2012.04.005 . .

TY  - JOUR
AU  - Vlahović, Milica M.
AU  - Savić, Maja M.
AU  - Martinović, Sanja
AU  - Boljanac, Tamara
AU  - Volkov-Husović, Tatjana
PY  - 2012
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2244
AB  - Sulfur concrete was prepared by using the following initial components: sand as an aggregate, modified sulfur binder, and alumina as a filler. Portland cement concrete was made of the same aggregate, cement and water. The durability of prepared concrete samples was tested in 10% solution of HCl as a function of immersion time. The changes in mechanical strength and mass of the samples were periodically measured. Sulfur concrete exhibited limited mechanical strength and mass loss, while physico-mechanical properties of Portland cement concrete regressed rapidly. The image analysis used for surface destruction monitoring, performed by Image Pro Plus Program for determination of damaged surface area and original surface area before acid resistance testing, showed the similar results. Based on the image analysis results, model for predicting the mechanical strength degradation during durability testing was presented. The fact that calculated and experimental strength values were not far apart proved the validity of the proposed model.
PB  - Elsevier Sci Ltd, Oxford
T2  - Materials & Design
T1  - Use of image analysis for durability testing of sulfur concrete and Portland cement concrete
EP  - 354
SP  - 346
VL  - 34
DO  - 10.1016/j.matdes.2011.08.026
ER  - 

@article{
author = "Vlahović, Milica M. and Savić, Maja M. and Martinović, Sanja and Boljanac, Tamara and Volkov-Husović, Tatjana",
year = "2012",
abstract = "Sulfur concrete was prepared by using the following initial components: sand as an aggregate, modified sulfur binder, and alumina as a filler. Portland cement concrete was made of the same aggregate, cement and water. The durability of prepared concrete samples was tested in 10% solution of HCl as a function of immersion time. The changes in mechanical strength and mass of the samples were periodically measured. Sulfur concrete exhibited limited mechanical strength and mass loss, while physico-mechanical properties of Portland cement concrete regressed rapidly. The image analysis used for surface destruction monitoring, performed by Image Pro Plus Program for determination of damaged surface area and original surface area before acid resistance testing, showed the similar results. Based on the image analysis results, model for predicting the mechanical strength degradation during durability testing was presented. The fact that calculated and experimental strength values were not far apart proved the validity of the proposed model.",
publisher = "Elsevier Sci Ltd, Oxford",
journal = "Materials & Design",
title = "Use of image analysis for durability testing of sulfur concrete and Portland cement concrete",
pages = "354-346",
volume = "34",
doi = "10.1016/j.matdes.2011.08.026"
}

Vlahović, M. M., Savić, M. M., Martinović, S., Boljanac, T.,& Volkov-Husović, T.. (2012). Use of image analysis for durability testing of sulfur concrete and Portland cement concrete. in Materials & Design
Elsevier Sci Ltd, Oxford., 34, 346-354.
https://doi.org/10.1016/j.matdes.2011.08.026

Vlahović MM, Savić MM, Martinović S, Boljanac T, Volkov-Husović T. Use of image analysis for durability testing of sulfur concrete and Portland cement concrete. in Materials & Design. 2012;34:346-354.
doi:10.1016/j.matdes.2011.08.026 .

Vlahović, Milica M., Savić, Maja M., Martinović, Sanja, Boljanac, Tamara, Volkov-Husović, Tatjana, "Use of image analysis for durability testing of sulfur concrete and Portland cement concrete" in Materials & Design, 34 (2012):346-354,
https://doi.org/10.1016/j.matdes.2011.08.026 . .

TY  - JOUR
AU  - Vlahović, Milica M.
AU  - Martinović, Sanja
AU  - Boljanac, Tamara
AU  - Jovanić, Predrag
AU  - Volkov-Husović, Tatjana
PY  - 2011
UR  - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/1893
AB  - Durability of sulfur concrete with different fillers, as well as Portland cement concrete, was tested in the solutions of HCl, H(2)SO(4), and NaCl. Regarding mass changes, in the solutions of HCl and H(2)SO(4) sulfur concrete with talc and fly ash exhibited higher durability, while in NaCl samples with alumina and microsilica were better. The type of filler did not affect durability regarding compressive strength. Strength loss was higher in the solution of HCl comparing to H(2)SO(4), while negligible in NaCl which is in accordance with apparent porosity increase. Portland cement concrete after two months lost 20% of mass.
PB  - Elsevier Sci Ltd, Oxford
T2  - Construction and Building Materials
T1  - Durability of sulfur concrete in various aggressive environments
EP  - 3934
IS  - 10
SP  - 3926
VL  - 25
DO  - 10.1016/j.conbuildmat.2011.04.024
ER  - 

@article{
author = "Vlahović, Milica M. and Martinović, Sanja and Boljanac, Tamara and Jovanić, Predrag and Volkov-Husović, Tatjana",
year = "2011",
abstract = "Durability of sulfur concrete with different fillers, as well as Portland cement concrete, was tested in the solutions of HCl, H(2)SO(4), and NaCl. Regarding mass changes, in the solutions of HCl and H(2)SO(4) sulfur concrete with talc and fly ash exhibited higher durability, while in NaCl samples with alumina and microsilica were better. The type of filler did not affect durability regarding compressive strength. Strength loss was higher in the solution of HCl comparing to H(2)SO(4), while negligible in NaCl which is in accordance with apparent porosity increase. Portland cement concrete after two months lost 20% of mass.",
publisher = "Elsevier Sci Ltd, Oxford",
journal = "Construction and Building Materials",
title = "Durability of sulfur concrete in various aggressive environments",
pages = "3934-3926",
number = "10",
volume = "25",
doi = "10.1016/j.conbuildmat.2011.04.024"
}

Vlahović, M. M., Martinović, S., Boljanac, T., Jovanić, P.,& Volkov-Husović, T.. (2011). Durability of sulfur concrete in various aggressive environments. in Construction and Building Materials
Elsevier Sci Ltd, Oxford., 25(10), 3926-3934.
https://doi.org/10.1016/j.conbuildmat.2011.04.024

Vlahović MM, Martinović S, Boljanac T, Jovanić P, Volkov-Husović T. Durability of sulfur concrete in various aggressive environments. in Construction and Building Materials. 2011;25(10):3926-3934.
doi:10.1016/j.conbuildmat.2011.04.024 .

Vlahović, Milica M., Martinović, Sanja, Boljanac, Tamara, Jovanić, Predrag, Volkov-Husović, Tatjana, "Durability of sulfur concrete in various aggressive environments" in Construction and Building Materials, 25, no. 10 (2011):3926-3934,
https://doi.org/10.1016/j.conbuildmat.2011.04.024 . .