Journal of Sustainable Architecture and Civil Engineering 2016/2/15
66

*Corresponding author: josemanuel.gomez@upc.edu 

Total Replacement of Recycled 
Aggregate and Treated 
Wastewater: Concrete 
Recycling in Extremis

http://dx.doi.org/10.5755/j01.sace.15.2.15464

Ramírez-Tenjhay Mayanin Gisela, Vázquez-González Alba Beatriz
Universidad Nacional Autónoma de México, Facultad de Ingeniería, División de Ingeniaría Civil y 
Geomática, Circuito Exterior s/n Col. Ciudad Universitaria C.P. 04510 Del. Coyoacán México D.F.

Gómez-Soberón José Manuel*
Universidad Politécnica de Cataluña, Escuela Politécnica Superior de Edificación de Barcelona, Av. 
Doctor Marañón, 44-50, 08028, Barcelona, Spain

Cabrera-Covarrubias Francisca Guadalupe
Universidad Politécnica de Cataluña, Escuela Técnica Superior de Ingenieros de Caminos, Canales y 
Puertos de Barcelona, Calle Jordi Girona, 1-3 Edificio C 2, 08034 Barcelona, Spain

Received  
2016/07/07

Accepted after  
revision 
2016/09/20

Journal of Sustainable 
Architecture and Civil Engineering
Vol. 2 / No. 15 / 2016
pp. 66-75
DOI 10.5755/j01.sace.15.2.15464 
© Kaunas University of Technology

Total Replacement 
of Recycled 
Aggregate and 
Treated Wastewater: 
Concrete Recycling in 
Extremis

JSACE 2/15

Introduction

Million tons of construction and demolition waste (CDW) are generated every year around the world, and 
most of them are not adequately disposed, generating significant pollution on water, soil and air. Additionally, 
the use of freshwater in industrial processes, such as the production of cement, concrete manufacturing 
and curing for newly-built structures; has damaged the health of our freshwater ecosystems, reducing their 
volume and hindering their natural cycle of renovation. Therefore, the incorporation of recycled aggregate 
(RA) and treated wastewater (TW) as substitutes for the usual aggregates (UA) and freshwater, could 
generate significant environmental benefits. In this research, a comparative analysis of the experimental 
results of the properties of fresh and hardened concrete with different replacement percentage of UA for 
RA, is presented; and as an innovation the use TW. The results show that, regardless of the replacement 
percentage and use of treated wastewater, a concrete with RA and TW (recycled concrete in extremis, CRiE) 
had a satisfactory and acceptable or equivalent performance, not differing significantly from the performance 
of conventional concrete (CC), confirming that the use of RA for concrete building is feasible. 

KEYWORDS: recycled aggregates, recycled concrete, sustainable materials, treated wastewater. 

Concrete is the second most consumed material by man after water, it is estimated that the global 
annual average production of concrete is about one ton for every human being (World Business 
Council for Sustainable Develop 2009); therefore, the use of UA (main component of concrete) is 
increased along with cement production and use of concrete (Marie and Quiasrawi 2012).

On the other hand, millions of tons of CDW are generated (construction processes, demolition 
and restoration works in structures and buildings) (Suarez et al. 2006); as an example, only in 
Europe, United States and Japan, more than 900 million tons are generated each year (World 
Business Council for Sustainable Develop 2009). Because of that, it is important to search for new 
more-suitable alternatives for the environment, being the use of the RA of CDW, one of the most 
feasible, reducing the consumption of UA in the production of cement and concrete.



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Journal of Sustainable Architecture and Civil Engineering 2016/2/15

The most ancient use of RA is on ancient Rome Empire roads, and afterwards, generally in Europe, 
at the end of World War II (Shing Chai Ngo 2004), from which, diverse documented researches 
have been reported promising results obtained with its use. In Japan, with more than a quarter 
century in the investigation of possible applications, there are achievements of its use, mainly 
as sub-base material in road construction (up to 96% of RA, in 2000) (Rao et al. 2007). However, 
although it has been demonstrated that the use of RA contributes to reducing the CDW and the 
use of the UA, these are considered as a low-quality materials, as their virgin properties (mechan-
ical, physical and chemical) can be affected (Marinkovic et al. 2010). Additionally, the use of fresh 
water on the industry has caused an excessive extraction of groundwater sources, inducing to an 
excessive demand of surface water, and on the other hand, at the international level, an emerging 
critical environmental problem due to the lack of availability of new sources of supply (Van Den 
Heede and De Belie 2012).

There are previous investigations that address the search for new alternative sources of wa-
ter supply for the production of concrete such as: water polluted with minerals, salts and other 
contaminants as those from streams, lakes and the sea (McCarthy 2008). These studies are fo-
cused on analyzing the effects presented in fresh and hardened concrete behavior, concluding that 
the results are not always satisfactory, since in some circumstances the concrete compressive 
strength decreases. Another alternative that has been explored (common practice in Germany) is 
the use of wash water from concrete, which is composed mostly of mixing water, cement and fine 
aggregate remnants, obtaining in general adequate results, and a similar behavior with regard 
to setting time, compressive strength, alkalinity and the chloride content, have been established 
(Silva and Naik 2010).

Finally, there are not many studies about the use of TW in the concrete production, so there are 
still unknown aspects to consider in terms of reaction that they might have on the concrete, due to 
the possible presence of contaminants. Therefore, the use of RA and TW in the production of con-
crete has significant potential to solve the problem that represents the final disposal of the CDW, 
the preservation of natural resources and the potential damages to the environment.

The use of RA from the CDW leads to a sustainable practice in the construction industry, as well 
as the consumption of alternative sources of water supply such as TW; so the main goal of this 
research is to establish the feasibility of using RA and TW for the manufacture of a new recycled 
concrete, calling it CRiE, which potentially have the ability to face obstacles precluding the use 
of RA, strengthen and improve the legislation to develop recycled materials, and provide users 
reliability to use them.

The construction materials employed in the experimental process were Portland Composite Ce-
ment (CPC) Type II 30R RS classified in accordance with NMX C414 ONNCCE 2004 (Anon n.d.) 
and ASTM C-595 (ASTM Standard C595/C595M 2016) standards. The UA were acquired to a lo-
cal quarry, whereas the RA were obtained from “Concretos Reciclados”, factory in México City 
(19°19’12.3”N 99°03’16.2”W) which processes aggregates from CDW (Ramos Guevara 2007). The 
recycled coarse aggregate (RCA) used was produced from concrete waste graded in accordance 
with ASTM C 33 standard ASTM (Standard C33/C33M 2016), while the recycled fine aggregate 
(RFA) came from the fine remnants of the RCA crushing process.

It has been established that the quality of aggregates partially determines the characteristics of 
the concrete that contains them (in particular its strength and durability) (Paul 2011), standing 
out as most important some physical characteristics; its density, bulk density, water absorption, 
porosity, particle size distribution (including its texture and shape). The physical characterization 
obtained for the UA and RA used in this research are presented in Table 1, along with the stan-
dards under which the tests methods were carried out.

Materials



Journal of Sustainable Architecture and Civil Engineering 2016/2/15
68

The D of UA used are within the normal range (2.4 to 2.9 g/cm3) (Kosmatka et al. 2004); while 
the RA values referenced in the literature indicate that they decrease up to 10% compared to the 
UA (Marie and Quiasrawi 2012) (Marinkovic et al. 2010). Therefore, both aggregates used in this 
research have been considered suitable and appropriate. It is worth mentioning that the usual 
coarse aggregates (UCA) are 0.06 g/cm3 heavier than the RCA, being the fine fractions those with 
the most significant differences (0.2 g/cm3).

A high WA does not necessarily make the aggregates unsuitable; however, this could become in 
certain circumstances, an indicator of inadequate performance for concrete properties. As it is 
observed, the WA for both RA is greater than UA (6.03 and 14.38% in RCA and RFA, respectively). 
If RA fractions are compared, the RFA fraction exceeds 7.1% of RCA; these particular variations 
in the WA of RA is known and widely accepted to be attributed to old mortar adhered to the ag-
gregate particles (Malešev et al. 2010; Thomas et al. 2016; Descarrega 2011; de Brito and Robles 
2010; Silva et al. 2014; Marie and Quiasrawi 2012; Rao et al. 2007; Marinkovic et al. 2010; Paul 
2011) (more porous), which concentrates on the RFA fraction by the effect of crushing process in 
the aggregates (mortar weaker than UA).

The BD represents the weight and space occupied by the aggregates, pores and gaps found be-
tween the particles, this property affects the demand for cement and influences the required pro-
portion of coarse aggregate (CA) in the mix design (Kosmatka et al. 2004). The difference of BD 
between the RCA and UCA studied can be attributed to particles angularity of the RCA (concrete 
fracturing process and subsequent trituration), which causes an increase in the amount of gaps 
(poor particle arrangement), while UCA has a less aggressive production and because of its origin 
it has more rounded particles allowing a better particle arrangement. However, in despite of the 
previous differences and their implications, both aggregates are classified as suitable for a struc-
tural normal weight concrete (Kosmatka et al. 2004).

The FM describes fine aggregate (FA) particle size and thickness (bigger particles tend to have 
a higher FM), it sets the minimum amount of FA needed to fill the gaps between the CA, thus 
improving the workability of concrete (“lubricant” function for CA). The RFA of this investigation 
reached a FM above US standards (2.3 - 3.1) (ASTM Standard C33/C33M 2016), when compared to 
a usual fine aggregate (UFA), RFA has a higher FM; which must be considered to understand and 
explain the properties of concrete.

Granulometric profiles for RCA, UCA, RFA and UFA were tested using the standard specification 
ASTM C33 (ASTM Standard C33/C33M 2016) establishing the distribution of their particles siz-
es, the granulometric curves of the four aggregates used are shown in Fig. 1 and Fig. 2, along 

Table 1 
Physical properties of 

aggregates

Property/Classification ASTM RCA UCA RFA UFA

Density (D) [g/m3]
C127

2.23 2.29
--- ---

Water Absorption (WA) [%] 10.48 4.45

Density (D) [g/m3]
C128 --- ---

2.11 2.31

Water Absorption (WA) [%] 17.58 3.20

Bulk density (BD) [kg/m3] C29 1254.99 1376.21 --- ---

Fineness modulus (FM) C33 --- --- 4.00 2.50

Nominal maximum size (NMS) [mm] C33 25.00 25.00 --- ---



69
Journal of Sustainable Architecture and Civil Engineering 2016/2/15

with the standard limits. The CA 
(recycled and usual) meet the 
recommended particle distri-
bution limits; while FA denoted 
that both recycled and usual are 
outside the standard limits (the 
UFA slightly above the upper 
limit and RFA far below the low-
er limit); so to obtain a suitable 
particle size, the RFA should 
be corrected or compensated 
by blending particles of differ-
ent sizes. Notwithstanding the 
above, no changes have been 
established in any of the granu-
lometric profiles of aggregates, 
assuming that the most com-
mon granulometric profiles are 
never perfect (naturally), and 
that this is a more common op-
tion for manufacturing an in-si-
tu concrete and more practical 
for industry.

Fresh water used in concrete 
mixtures was obtained from 
water supply facilities of the 
National Autonomous Univer-
sity of México (19°19’54.156” 
N, 99°11’5.647” W), satisfying 
the Mexican standards in accor-
dance with the NOM-127-SSA 
(NOM-127-SSA1-1994 2010) 
that establishes permissible 
limits for fresh water quality, 

Fig. 1 
Coarse aggregates 
granulometric curve

Fig. 2 
Fine aggregates 
granulometric curve

changes have been established in any of the granulometric profiles of aggregates, assuming that the 
most common granulometric profiles are never perfect (naturally), and that this is a more common 
option for manufacturing an in-situ concrete and more practical for industry. 
 

 
Fig. 1. Coarse aggregates granulometric curve 

 

 
Fig. 2. Fine aggregates granulometric curve  

Fresh water used in concrete mixtures was obtained from water supply facilities of the National 
Autonomous University of México (19°19'54.156" N, 99°11'5.647" W), satisfying the Mexican 
standards in accordance with the NOM-127-SSA (NOM-127-SSA1-1994 2010) that establishes 
permissible limits for fresh water quality, whereas the treated wastewater was obtained from the 
wastewater treatment plant "Cerro de la Estrella" (WTP-CE) located in México City (19°20'12.2"N 

changes have been established in any of the granulometric profiles of aggregates, assuming that the 
most common granulometric profiles are never perfect (naturally), and that this is a more common 
option for manufacturing an in-situ concrete and more practical for industry. 
 

 
Fig. 1. Coarse aggregates granulometric curve 

 

 
Fig. 2. Fine aggregates granulometric curve  

Fresh water used in concrete mixtures was obtained from water supply facilities of the National 
Autonomous University of México (19°19'54.156" N, 99°11'5.647" W), satisfying the Mexican 
standards in accordance with the NOM-127-SSA (NOM-127-SSA1-1994 2010) that establishes 
permissible limits for fresh water quality, whereas the treated wastewater was obtained from the 
wastewater treatment plant "Cerro de la Estrella" (WTP-CE) located in México City (19°20'12.2"N 

whereas the treated wastewater was obtained from the wastewater treatment plant “Cerro de la 
Estrella” (WTP-CE) located in México City (19°20’12.2”N 99°04’34.0”W), which meets the Mexican 
quality parameters corresponding to the maximum permissible contaminants for treated waste-
water to be used in public services with direct human contact NOM-003-SEMARNAT (NOM-003-
SEMARNAT-1997 2003).

To assess the possibility of using water from the WTP-CE as an alternative source for mixing 
water in concrete, some tests were conducted (see Table 2). The results are compared with the 
maximum limits set by ASTM C 94 (ASTM Standard C94/C94M 2016) and NMX-C-122-2004 (NMX-
C-122-ONNCCE-2004 2004) (North American and Mexican standards, respectively); in both cases, 
all the required parameters are met except the content of fats and oils. The content of fats and 
oils can affect the development of concrete strength; it has been recommended that the content of 
mineral oil will not exceed 2.5% in cement weight (Kosmatka et al. 2004). Therefore, it has been 
considered that water of the WTP-CE will not cause significant effect on the strength of concrete 
(at least for its particular effect).



Journal of Sustainable Architecture and Civil Engineering 2016/2/15
70

Several investigations (Kou 2006; Moriconi n.d.; Marie and Quiasrawi 2012; Shing Chai Ngo 2004; 
Malešev et al. 2010) have shown that concrete from mixes containing up to 30% of RCA have 
lower mechanical properties than concrete with UA, on the another hand, it is also known that 
compressive strength for CC is directly correlated to water-cement ratio (w/c); therefore in this 
investigation both criteria were considered as design parameters in the mixtures studied.

To ensure workability (without use of additives) the slump range of fresh concrete selected was 
80-100 mm and in order to achieve a concrete strength of 25 MP (structural concrete) a w/c ratio 
of 0.62 was used for all mixtures. Three types of mixtures were defined to verify the feasibility of 
replacing UCA with RCA; a control concrete mixture (100% UA) and two with RCA (25% and 30% 
replacement of UCA with RCA. Additionally, to evaluate the feasibility of using a CRiE, the control 
concrete mixture was done using TW and two mixtures were done using 100% of RCA and RFA 
(one with fresh water and the other one with TW).

The concrete mix design was done using absolute volume method considering the properties ob-
tained in the characterization of the UA and RA (Kosmatka et al. 2004); in which the masses pro-
portions are determined assuming the aggregates are in saturated surface dry condition (SSD), 
then these are corrected by absorption and the moisture content of the aggregates. Concrete mix 
design in SSD is shown in Table 3. 

The incorporation sequence of materials into the mixer could have a significant effect on the uni-
formity of concrete (ASTM Standard C94/C94M 2016), so the method used for the mixture process 
was following ASTM C 192 (ASTM Standard C192/C 192M 2016). Fresh concrete properties were 
determined in accordance with established standards: slump (S), air content (Ar) and unit weight 
(UW), according to the ASTM C 143(ASTM Standard C143/C 143M 2015), ASTM C 231 (ASTM Stan-
dard C 231 2014) and ASTM C 138(ASTM Standard C138/C138M 2016), respectively.

Cylindrical specimens of 150 mm x 300 mm were made for mechanical test, the conditions for 
making and curing the specimens were carried out in accordance with ASTM C192 (ASTM Stan-
dard C192/C 192M 2016). Compressive strength testing was performed according to ASTM C39 

Table 2 
Quality parameters of 

treated wastewater

Parameters/Standards
ASTM C 94

ppm
NMX-C-122

ppm
Water from 

WTP-CE

Chlorides as Cl:

 _ Prestressed concrete on in bridge decks (maximum)
 _ Other reinforced concrete in moist environment or con-
tact with metals (maximum)

1.17500 600

1000 1000

Sulfate as SO4 3000 3500 70

Alkalies as Na+ 600 450 97

Total Alkalies as Na+ 600 450 97

Carbonates as CO3 --- 600 140

pH (H+) --- ≥ 6.5 7.52

Organic material --- 150 22

Suspended solids in natural water --- 2000 6

Suspended solids in recycled wastewater * --- 35000 6

Fats and oils --- 0 0.056

* Wash water used for washing and cleaning mixer trucks, concrete pumps and other equipment is considered as recycled water.

Methodology



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Journal of Sustainable Architecture and Civil Engineering 2016/2/15

(ASTM Standard C39/C 39M 2016) using SATEC SF-1U UNIVERSAL tensile and compressive tes-
ter, using neoprene pads in both ends of the specimens (ASTM C1231 (ASTM Standard C1231/C 
1231M 2015)); repetitiveness per variable was two specimens, at 14 and 28 days.

In addition, an analysis of scanning electron microscopy (SEM) was performed in two specimens 
of concrete (C and CRiE), in order to clarify the behavior of hardened concrete, the technique was 
performed with the microscope JOEL (JSM-651), taking and then conditioning a representative 
fraction of each specimen.

Aggregates

Mix with content of RCA Mix with content of TW

C R25 R30 C* Cw CRiE

RF=0 RF=25 RF=30 RF=100 RF=0 RF=100

UCA 963 703 665 --- 963 ---

RCA --- 237 281 816 --- 816

UFA 687 667 661 --- 687 ---

RFA --- --- --- 723 --- 723

C = control, RF= replacement factor, R25 and R30 = mix containing 25% and 30% of RA, C*= total replacement with RCA and 
RFA, Cw= control mix with TW, and CRiE= C* mix with TW. 

Table 3 
Mix design in SSD

Results and 
discussion

Table 4 
Testing results of fresh 
concrete

Properties

Mix with content of RCA Mix with content of TW

C R25 R30 C* Cw CRiE

RF=0 RF=25 RF=30 RF=100 RF=0 RF=100

Ar [%] 2.4 2.4 2.6 2.7 2.5 2.8

S [mm] 95 90 90 80 90 85

UW [kg/m3] 2132 2109 2115 2046 2144 2075

The results for fresh concrete testing are showed in Table 4. The Ar for a CC is in a range from 
2% to 3% (Kosmatka et al. 2004) (concretes without air entraining admixtures); in this research, 
the Ar for the mixes is between 2.4% and 2.8%, so all mixtures are in the usual Ar range without 
significant differences between them. Therefore, the effect of using RCA, RFA or TW-together or 
separately, regarding this property, does not affect the mixtures studied.

It has been established that the Ar is directly correlated to the S (Kosmatka et al. 2004); likewise, 
the values obtained are within the range considered in the mix design (80 to 100 mm). However as 
operating experience of its use, C* and CRiE mixtures had poor workability and rough texture due 
to a high content of thick particles and greater WA of RFA; resulting in mixtures with low natural 
compaction and difficult to place in practice.

The highest UW corresponds to the mixture Cw, followed by C (with minimum difference), and the 
lowest belongs to C*; summarizing, the variation between all the samples studied only reached 
4.5%, consistent with previous studies (Malešev et al. 2010).

The average results of the compressive strength of the specimens appear in Fig. 3, where two 
aspects of common behavior can be perceived: in the first, the results obtained at 14 days always 
manage to reach 86% of the design strength (Kosmatka et al. 2004); and second, the design 
strength is met; 25MPa (except CRiE).



Journal of Sustainable Architecture and Civil Engineering 2016/2/15
72

Fig. 3 
Concrete strength

Fig. 4
SEM image with x500 

zoom: a) usual concrete, 
b) concrete CRiE

Analyzing the results of the specimens with different RF, a correlation was found between the RF 
and strength loss; 2% and 3% (R25 and R30 respectively with respect to C) at age of 28 days. In the 
other hand, comparing specimens Cw with respect to C, strength loss is 5.2% (both ages of study); 
and the difference between C* with CRiE (where also the only variable factor is TW), the compres-
sive strength decreases by 3.5% and 1.2% for the 14 and 28 days, respectively. Finally, concerning 
the proposal for RF = 100%, were the first variable factor are RCA and RFA (C*) the strength loss 
with respect to C is 10.4% and 6.8% at 14 and 28 days, respectively.

As a hypothesis for the above behavior, in addition to adverse effects due to the physical proper-
ties of the RA (low D, high porosity), on the concrete mechanical behavior; it is suggested that the 
high porosity, the old adhered mortar on the original aggregates (higher concentration in the fine 
fraction of the aggregate), and the creation of new weaker areas around the aggregates called 
Interfacial Transition Zone (ITZ) - which is formed between a recycled aggregate (with adhered 
mortar) and the new concrete mortar; are the causes of strength loss. In order to validate this, im-
ages (SEM) were performed; seeing that in concrete with RA replacement these areas are wider 
with a noticeable increase present in the matrix (see Fig. 4).

Finally, because of the TW chemical studies and the minimum variations of strength between CRiE 
and a CC, it is concluded that the possibility of using this type of water in the creation sustainable con-
crete is feasible, practical and appropriate; thereby mitigating the demand of fresh water in the indus-
trial manufacturing of concrete, besides contributing to the rational use of nonrenewable resources.

 

new mortar 

usual 
aggregate 

ITZ 

a) new mortar 

recycled 
aggregate 

ITZ 

b) 

 

new mortar 

usual 
aggregate 

ITZ 

a) new mortar 

recycled 
aggregate 

ITZ 

b) ba



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Journal of Sustainable Architecture and Civil Engineering 2016/2/15

Based on the research conducted, there is evidence of the feasibility to use (limited in some as-
pects of resistance and durability) the RCA and the TW as components of recycled concrete; con-
sidering this as a truth, the possible applications of recycled concrete may not be 100% compara-
ble to the CC, but the rational use of materials in the constructive elements of low requirements 
makes possible its application. The above, allows to give solution to CDW and the TW, promoting 
the sustainability and the use of recycled materials in construction.

From the results of this research (tests on concrete fresh and compressive strength), it was ob-
served that all mixtures of concrete containing the TW presented generally favorable values ac-
cording to the regulations for concrete (even that the TW does not satisfy the limits of contents of 
oils and fats), therefore its use could be a viable alternative to reduce the consumption of fresh 
water through the use of TW. The TW of this study, can be considered as a source of water ac-
ceptable for the manufacturing of concrete; however, it is mandatory to carry out all previous 
analysis necessary that allow to guarantee the fulfillment of the regulation tolerances to ensure 
it as a constituent element of a concrete. In cases where these requirements are not achieved, it 
will be necessary to conduct a study of the possible affectation of the contaminant in the concrete, 
entailing that to use them, most pollutant substances that can cause deterioration in the strength 
and durability, must be removed. So the TW will have to be submitted to a constant control in 
wastewater treatment plants.

The RCA used are of high quality and no significant differences were present compared with UA, 
so it is possible to obtain a concrete with a satisfactory mechanical behavior, comparable with a 
CC. Moreover, the RFA has characteristics of poor quality so that it is unfeasible for structural use, 
however can be used in non-structural concrete elements. 

The D and BD of RCA are not significantly lower, so that it meets the pre-established recommen-
dations. In addition, workability, Ar and S do not show substantial effects in any of the treatments 
where RCA was used. In the mixture CRiE one centimeter less of slump was obtained with respect 
to the control mixture, so its value is insignificant and requires no correction for practical imple-
mentation. Finally, the WA of the RCA is greater with respect to a UCA, however, this does not af-
fect the characteristics of the concrete. This increase of the WA in the RCA, can be decisive for the 
behavior of durability of the concrete recycled to its resistance to the freeze-thaw (cold climates); 
for which, will be necessary the accomplishment of future research that demonstrate this possible 
affectation to the durability (process of micro-cracking, number of freeze-thaw cycles tolerable, 
additions of improvement of the concrete, palliative concreting processes, etc.).

Finally, there is a clear need to expand this research; since more tests and series of different types 
and origins of the RCA and TW might generate a wide statistics that give strength and solidity to 
constructive, practical, and safe applications. The previous comment is based on the origin of the 
RCA and TW materials, with contents of very variable, complex and slightly usual pollutants in the 
composition of the concretes. Future studies, which established the tolerances of each pollutant 
in the different aspects of the strength and durability of concrete (separately or combined), as well 
as the search of criteria for the establishment of applications with low solicitations, will mark the 
future, acceptance and inclusion in the regulations of these new sustainable concrete. For the 
case of the TW, contents of substances organic, acidifying and reactive with the chemistry of the 
cement; as well as for the RCA, its origin (type of concrete which comes), process of crushing and 
shape of particles, are considered to be important variables to study in future research, to obtain 
a broader understanding of the concrete that include them.

Conclusions

The authors express thanks to: research Project S-01117 from CTT-UPC, to EPSEB-UPC, to the 
Department CAII-EPSEB, to DEPFI-UNAM and to the scholarships program for Master Degree 
studies by CONACYT.

Acknow-
ledgment



Journal of Sustainable Architecture and Civil Engineering 2016/2/15
74

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MAYANIN GISELA 
RAMÍREZ-
TENJHAY 

MSc student  

National Autonomous 
University of Mexico, 
Faculty of Engineering, 
Civil and Geomatic 
Engineering 
Division

Main research area 

Recycled concrete, 
sustainable 
construction

Address 

Circuito Exterior 
s/n Col. Ciudad 
Universitaria C.P. 04510 
Del. Coyoacán México D.F. 
Tel. +52 5622 8001
E-mail: mayanin.
tenjhay@outlook.com

ALBA BEATRIZ 
VÁZQUEZ-
GONZÁLEZ 

Full time Professor

National Autonomous 
University of Mexico, 
Faculty of Engineering, 
Civil and Geomatic 
Engineering  
Division

Main research area 

Recycled concrete, 
sustainable 
construction

Address 

Circuito Exterior 
s/n Col. Ciudad 
Universitaria C.P. 04510 
Del. Coyoacán México D.F. 
Tel. +52 5622 8001
E-mail: mayanin.
tenjhay@outlook.com

JOSÉ MANUEL 
GÓMEZ- 
SOBERÓN 

Full time Professor

Polytechnic University 
of Cataluña, School of 
Building Construction of 
Barcelona, Department of 
Building Architectural II 

Main research area 

Concrete recycled, 
porous structure of 
concrete, sustainable 
construction, 
minimization, reuse and 
recycling in construction, 
ICT in teaching, virtual 
campus teachers

Address 

Doctor Marañón, 44-50, 
08028, Barcelona, Spain 
Tel. +34 93 401 6242
E-mail: josemanuel.
gomez@upc.edu

FRANCISCA 
GUADALUPE CABRERA-
COVARRUBIAS

PhD student  

Polytechnic University of 
Cataluña, Barcelona  
School of Civil  
Engineering

Main research area 

Recycled concrete, 
sustainable construction

Address 

Calle Jordi Girona,  
1-3 Edificio C 2, 08034 
Barcelona, Spain
Tel. +34 93 401 6900
E-mail: guadalupe.
cabrera04@gmail.com

 

About the 
authors